System and method for remote monitoring and operation of personal computers

ABSTRACT

A system and method for accessing, controlling and monitoring a data processing device in which a video raster signal from the data processing device is analyzed to determine the information displayed on a video display monitor attached to the data processing device is used. The video raster signal is converted to a digital form and a cyclic redundancy check is performed on the digital data to determine the information contained in the video raster signal and to generate a compressed representation of that information. The information may then easily and quickly be transmitted to a remote location for analysis and review. Additionally, commands from the remote location can be transmitted to the system to control the data processing device.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent applicationSer. No. 07/966,081 filed Oct. 23, 1992, now U.S. Pat. No. 5,566,339.

This specification includes a microfiche appendix containing 3 ficheshaving 255 frames.

FIELD OF THE INVENTION

The present invention relates generally to a method and apparatus forpersonal computer (PC) monitoring and control and more specifically to amethod and apparatus for enabling a PC to which the apparatus isconnected (hereinafter referred to as a “Host” PC) to be accessed,restarted, operated and/or controlled remotely by another PC(hereinafter referred to as a “Remote” PC) using standard public utilitytelephone lines or direct cabling. The invention further permits aRemote PC to access Host processing status information and/or restart(i.e. reboot) the Host PC without Central Processing Unit (CPU) supportfrom the Host PC.

BACKGROUND OF THE INVENTION

Millions of PCs are presently in use. Each PC includes various hardwarecomponents including a CPU, keyboard, mouse, video display adaptercard/circuit (hereinafter referred to as “VDAC”), video display monitor(hereinafter referred to as “VDM”), and/or one or more mass storagedevices. Other special purpose hardware devices such as a modem, voiceor sound card, or network interface adapter card may be connected to orinstalled within a PC.

Presently, a VDM is normally either an analog or TTL (digital) displaydevice that connects to either a 15 pin or 9 pin receptacle on a PC'sVDAC. A PC's VDAC normally sends video signals to a VDM in either amonochrome, CGA, EGA, or VGA format known to persons familiar with thetrade. The present invention, however, is not to be limited to thesevideo formats and will operate with any video format when properlyconfigured. PC's may be accessed and controlled remotely by other PC'sby essentially two different types of processes. First, a hardwarenetwork interface adapter card or device may be installed or connectedto a PC. This interface device is then connected, either using a cableor through the airways using a wireless network interface device, toother PCs attached to a Local Area Network (LAN). All such devicesrequire Host CPU support (via network interface software installed inthe PC's memory) to permit a Remote PC to access or control a Host PC.Persons familiar with the trade refer to this type of process as “peerto peer” PC networking.

Second, a memory resident software system may be installed on a Host PChaving access to a modem which would then permit the Host PC to beremotely controlled over standard telephone lines by another Remote PChaving access to a modem and compatible memory resident interfacesoftware operating on the Remote PC. Again, in this case the ability ofthe Remote PC to control and access the Host PC depends on CPUprocessing support being provided by both PC's and a memory residentsoftware system being pre-installed on the Host PC to acknowledge andprocess an incoming call from the Remote PC.

In many cases control of a PC is not always practical or possibleremotely. Many PC based application software systems take over a PCcompletely and, due to memory restrictions or other processingconflicts, cannot co-exist with those software systems permitting RemotePC access. Moreover, even in cases where the required Host and Remoteaccess interface software has been successfully installed, if the Hostprocessor should lock-up or otherwise fail, remote users immediatelylose their ability to access the Host system. In such cases the Remoteuser would not be able to remotely access information displayed on theHost PC's VDM screen after the lock-up occurred. Information displayedon the VDM screen, however, usually indicates why the failure occurredand the status of processing at the point of failure, and therefore canbe particularly useful in analyzing the PC failure and in preventingfuture similar failures.

Numerous PC monitoring systems are presently available to automaticallyalert designated persons via pagers, pre-recorded voice alerts orelectronic mail when a PC or application running on a PC has failed.When such failures occur, the persons being notified may be in remotelocations (e.g. at home) not able to physically access the PC that hasfailed.

After a failure alert is issued, persons alerted typically have accessto a Remote PC, but may not be able to access a desired Host PC becausethe Host CPU has locked up and will no longer respond to user input, theapplication running on the Host system does not support or condoneRemote PC access, or the Host system does not have the required softwareinstalled to permit a Remote PC to access the Host PC. When a Host CPUhas locked up or a program error has occurred, vital information, as tothe exact nature of the problem which has occurred is often displayed onthe PC's VDM screen. Normally, this information must be viewed and/oranalyzed before corrective action can be taken. Devices presently existthat permit a PC to be remotely or automatically re-booted, which inmany cases restores normal processing after an alert is issued. However,persons alerted are reluctant to use such devices without first lookingat the PC's VDM screen to determine what may have caused the failure, sothat similar failures can be prevented. In other cases, information onthe VDM screen may be necessary to successfully re-start an applicationthat has failed from the point of failure.

Many PC users need to remotely monitor and control another PC, where,due to processing restrictions or limitations, it may not be possible touse the PC's processor to access a particular PC remotely. For example,for security reasons, a bank may wish to discreetly monitor PC usage bytellers or loan officers from a central, off-site location. As a secondexample, a Network Manager may wish to periodically remotely monitor andcontrol the activities of a dedicated network file server or tape backupworkstation. As a third example, unskilled on-site PC users may need asimple means to permit PC maintenance personnel to have extensive remoteaccess to their PCs, and particularly to a network file server, in theevent of trouble or failure.

Numerous software systems are available which are designed to link onePC with other PCs using modems connected via standard telephone lines.These systems permit a Host PC to be controlled by a Remote PC. Specialfunctions keys and menus are used by these software systems that permitthese products to operate a Host PC from a Remote PC as if the remoteuser was physically sitting at the Host PC. Examples of such packagesinclude Crosstalk, developed by Digital Communications Associates, Inc.,1000 Alderman Dr., Alpharetta, Ga. 30202-1000 (404-442-4000); ProcommPlus, developed by Datastorm Technologies Inc., 3212 Lemone Blvd,Columbia, Mo. 65201, (314-443-3282); or Unicom, developed by DataGraphics, P.O. Box 58517, Renton, Wash. 98058 (206-432-1201). Each ofthese products require processing support and memory from the Host PCand will halt if Host processing should lock-up or fail. Also, if theseproducts are not pre-installed on the Host PC, remote access will not bepossible and no provision is made by these products to save VDM screenhistory or to capture an active VDM screen when a PC has locked-up.Finally, these products assume software based control of the keyboardand/or mouse, as opposed to assuming physical control over the PC'skeyboard and/or mouse, which is less restrictive.

Network software utility programs exist that permit one workstation toaccess and control the activities of another workstation connected tothe network. Products that tall into this category include, Carbon Copyfor LANs, developed by Microcom Inc., 500 River Ridge Drive, Norwood,Mass. 02062 (617-551-1000); and Map Assist, developed by FreshTechnology Company, 1478 North Tech Boulevard, Suite 101, GilbertArizona, 85234 (602-497-4200). Similar to the other remote accessutility programs, these products require software resident in the HostPC's memory to operate. Neither remote control or access will bepossible if the Host PC should lock-up or fail.

Utility software programs exist that are designed to convert graphicsimage data captured by document scanners into text data, so that theresulting text data can be manipulated and edited using word processingsoftware products. Examples of such programs include, OmniPageProfessional, developed by Caere Corp, 100 Cooper Ct., Los Gatos, Calif.95030 (408-395-7000); Perceive, developed by Ocron, 3350 Scott Blvd.,#36, Santa Clara, Calif. 95054; TypeReader, developed by ExperVisionInc., 3590 N. First St., San Jose, Calif. 95134 (408-428-9444); andWordScan Plus, developed by Calera Recognition Systems, 475 PotreroAve., Sunnyvale, Calif. 94086 (408-720-8300). Such programs obtainsource input data from digitized output of static data files created bydocument scanners as opposed to capturing, decoding then converting totext the output signals of a PC's video display adapter cards/circuits(VDAC) as the signals are occurring (i.e. on a real time basis). Inaddition, such utility programs depend on CPU support from the PC wherethey are installed, cannot transmit data related to the status ofprocessing in the event the PC should fail, and provide for no remotekeyboard and/or mouse control.

Devices exist that permit using a central keyboard and monitor tocontrol and access multiple PC's. Examples of such products includeCommander, developed by Cybex Corporation, 2800-H Bob Wallace Ave.Huntsville, Ala. (205-534-0011); Master Console developed by RaritanComputer, Inc., 10-1 Ilene Court, Belle Mead, N.J. 08502; and Plexdeveloped by Data Vision Inc., 370 West Camino Gardens Blvd, Boca Raton,Fla., 33432 (407-482-3996). These products require the keyboard and PCinterface cables to be directly connected to one or more physical cableswitching device(s). The VDAC signals are merely boosted and transferredas video signals over direct dedicated cabling. No attempt is made toconvert the signal output of the VDAC to a digital form suitabletransmission over public utility telephone lines or other communicationnetwork. Similarly, the keyboard used by the central unit is connecteddirectly to each PC controlled with local wiring and no attempt is madeto control keyboards using the public telephone system or to supportkeyboards existing at both the remote console and Host PC.

Devices exist that transmit a composite (TV) video signal over atelephone line. Such products include the PhoneViewer, distributed byHome Automation Lab, 5500 Highlands Pkwy, Suite 450, Smyrna, Ga.30082-5141 and AT&T's video phone, developed by AT&T, 14250 ClaytonRoad, Baldwin, Mo. 63011, 1-800-437-9504. These products rely on a videocamera to periodically capture a picture which is then transmitted to ascreen on the remote caller's video phone. These systems convert thevideo camera images captured to bit-mapped graphical images. No attemptis made to decode the data captured into text data. Furthermore, suchproducts are not capable of decoding and transmitting the video signalsproduced by a PC's VDAC. If such products were used to simply snap apicture of the PC's VDM screen, the resulting data transmitted would beslow and of a poor quality, particularly if the PC video output changedduring the period when the video snapshot is being; taken. Moreover,none of these products provide a PC keyboard/mouse telephone interfacenecessary to control a Remote PC. Even if such an interface wereprovided, the user may require a separate phone line to access theRemote PC, so as to not interfere with the transmission of videographics image data derived from the composite video snapshot.

Devices exist that permit a video signal to be captured by a PC from anexternal analog video recording device, such as a video camera, and thesignal converted into a digital format suitable for display on a PC'sVDM using a video capture adapter card inserted into a PC. One suchdevice is the Smart Video Recorder manufactured by Intel Corp., P.O. Box58130, Santa Clara, Calif. 95052 (800-955-5599). Such devices require adedicated cable to be directly connected from the video capture adaptercard to the video recording device, and none of these products provide aPC keyboard/mouse telephone interface necessary to control a Remote PC.

Numerous devices exist that permit a PC to be re-booted remotely such asthe Sentry Remote Power Manager, developed by Server Technology, 2332-BWalsh Ave. Santa Clara, Calif. 95051 (408-988-0142), Tone OperatedSwitch (TOPS) developed by Black Box Corp., P.O. Box 12800, PittsburghPa. 15241 (412-746-5530) or TELEBOOT developed by Fox Network Systems,15200 Shady Grove Road, Suite 350, Rockville Md. 20750 (301-924-2264).Once such system is described in U.S. patent application Ser. No.07/966,081 filed Oct. 23, 1992 and assigned to assignee of the presentinvention, the contents of which are incorporated by reference herein.These devices, however, provide no remote video display orkeyboard/mouse interface capabilities.

U.S. Pat. No. 5,153,886 to Tuttle discloses a visual display signalprocessing system and method used for regression testing of computerhardware and/or software applications. The system disclosed in Tuttle,however, relies upon connection to the internal video adapter circuitryand does not operate to interpret video raster signals generated by thevideo display adapter circuit. Furthermore, the system disclosed inTuttle is intrusive since it requires a circuit card to be installedinto a computer to be tested, and cannot be easily connected to acomputing device using the existing standard interface connectors.

U.S. Pat. No. 5,084,875 to Weinberger et al. discloses a system forautomatically monitoring copiers from a remote location and allowingoperation of a copier from a remote location. Weinberger et al.,however, does not disclose a system suitable for use in remotemonitoring and control of a personal computer system or network, andfurther does not disclose a system which can monitor and forward videoraster signals generated by a remote computer system.

U.S. Pat. No. 5,124,622 to Kawamura et al. discloses a system for remotediagnosis of a numerical apparatus. Again, however, Kawamura et al. doesnot disclose a system which can monitor and forward video raster signalsgenerated by a remote computer system. Additionally, Kawamura et al.does not disclose a system for use in remote monitoring and control of apersonal computer system or network.

U.S. Pat. No. 5,237,677 to Hirosawa et al. discloses a monitoring andcontrolling system and method for a data processing system in whichreport of a fault occurrence is automatically effectuated to a remotelylocated supervision/control system. Hirosawa et al., however, fails todisclose a system that can monitor the video raster signals generated bya remote data processing system.

SUMMARY OF THE INVENTION

The present invention permits a Remote PC to access and control a HostPC. The system includes a microprocessor controlled computer hardwaredevice, (hereinafter referred to as a “Host Unit”), software programsoperating on the Host PC, and software programs operating on the RemotePC.

The connection between a Host PC and Remote PC can be accomplishedthrough either of two means. As a first means, a modem is connected tothe Remote PC's serial interface port and a compatible modem isconnected to a data interface port on the Host Unit. On this basis, aRemote PC could communicate with a Host site via a standard telephoneline linkage between the two modems. This means is hereinafter referredto as a “Modem Linkage”.

As a second means, a remote PC could be connected by a dedicated cablefrom a data transfer port of the PC (e.g. a serial or parallel port)directly to a data interface port on the Host Unit. This means ishereinafter referred to as a “Direct Line Linkage”. The Direct LineLinkage means supports greater data transfer rates than the ModemLinkage means and the Direct Line Linkage means avoids the need to usemodems. However, the Direct Line Linkage means does not provide the sameflexibility for off site remote access to a Host Unit as does the ModemLinkage means.

The Host Unit contains it's own microprocessor (or other computingcircuitry) designed to capture, interpret and store informationdisplayed on a Host PC's VDM screen from the video raster signal outputof the Host PC's VDAC (i.e. a video raster signal is that video outputsignal of a VDAC which serves as direct input into a VDM). VDM screendata collected in this manner permits a Remote user to access, obtain,view, and store Host PC current and previous VDM screen data on a RemotePC after linking the Remote PC to the Host Unit. VDM screen datacaptured, interpreted and stored by a Host Unit from the Host PC's VDACraster output may be either text or graphics (i.e. image) based and maybe in either color or monochrome. Host VDAC video raster signal outputdisplay formats captured and interpreted by a Host Unit includemonochrome, CGA, EGA, and VGA modes, which are known to persons familiarwith the trade, and similar techniques could be used for any displayformat.

In addition, the invention permits a Remote PC to (1) physicallyredirect keyboard and/or mouse control from a keyboard and/or mouseconnected to a Host PC at the Host Site to the keyboard and/or mouseconnected to the Remote PC, thereby allowing the Remote PC to fullycontrol keyboard and/or mouse input to the Host PC, (2) remotelyinitiate software programs installed on a Host PC necessary to transferfiles and data between the Host PC and Remote PC, (3) interconnect (i.e.daisy chain) multiple Host Units together so as to allow a Remote PC toswitch between different Host PC's during a single access session, and(4) cold boot a Host PC, when necessary by instructing the Host Unit totemporarily cut the AC power to the Host PC forcing it to perform a coldboot.

One embodiment of the present invention comprises (1) software installedon the Remote PC that permits the Remote PC to utilize a standard modemsuch as, for example, a Hayes 9600 baud Ultra modem, Hayes 2400 Smartmodem or Boca 14.4 for Modem Linkage, or a direct cable connection forDirect Line Linkage, to remotely access a Host Unit, thereby allowingthe Remote PC to communicate with the Host Unit and access/control aHost PC attached to the Host Unit; (2) a Host Unit, which is either (a)directly attached to a modem or remote PC or (b) connected to a RemotePC via another Host Unit (i.e. daisy chained) and is directly connectedto the keyboard input, optional mouse input, VDAC raster output and ACpower input interfaces of the Host PC; (3) software program filesinstalled on the Host PC that may be activated remotely to facilitatefile transfers between the Host and Remote PCs and (4) software programsrun on the Host PC during installation to permit the Host Unit attachedto the Host PC to automatically train itself how to decode the specificvideo raster output signals from the Host PC's VDAC.

Software installed on the Remote PC permits (1) accessing a Host PC sitein either a Modem Linkage or Direct Line Linkage mode, (2) initializinga modem attached to the Remote PC (including baud rate, andinitialization strings) necessary for a Modem Linkage mode, (3)maintaining a list of Host Units that may be accessed from the Remote PC(including the dialing information needed to call the Host modem that isused to access each Host Unit (when in a Modem Linkage mode), the IDnumber for each Host Unit, and the password needed to access each HostUnit), (4) completing a Modem or Direct Line Linkage from the Remote PCto a designated Host Unit, (5) displaying status information relating toa active connection on the Remote PC's VDM screen, (6) scanning the HostPC's VDM screen display history transferred from the Host Unit andstored on a mass storage device on the Remote PC, (7) setting thespecific procedure to be used by the active Host Unit to capture Host PCVDAC video raster output (i.e. text modes, graphic modes, etc. in eithermonochrome or color), (8) switching the Remote PC's keyboard and/ormouse from use as a normal Remote keyboard and/or mouse to use as thekeyboard and/or mouse for the Host PC, (9) accessing a Host PC forpurposes of viewing a Host PC's VDM activity without switching the HostPC's keyboard and/or mouse to the Remote PC's keyboard and/or mouse,(10) switching the keyboard and/or mouse back from use as Host PCkeyboard/mouse to use as a Remote keyboard/mouse, (11) initiating andcontrolling the transfer of data files between the Host and Remote PC,(12) communicating with the Host Unit using either standard telephonelines and modern communication protocols, when in a Modem Linkage mode,or a direct dedicated line, when in a Direct Line Linkage mode, (13)switching the Remote PC's VDM screen from a normal (i.e. Remote) VDMscreen mode to a Host screen mode where a Host PC's VDAC output data iscaptured (without Host PC CPU support) and transmitted by the Host Unitto the Remote PC and is displayed on the Remote PC's VDM screen in placeof the normal Remote PC's VDM screen display, (14) switching the RemotePC's VDM screen back from a Host PC video display to use as a Remote PCvideo display, (15) notifying the Host Unit to temporarily cut AC powerinput to the Host PC thereby forcing the Host PC to re-start, which iscommonly referred to in the trade as a “cold-boot,” (16) switchingbetween Host Units and the Host Unit's associated Host PC in cases wheremore than Host Unit is interconnected, (17) changing a Host Unit'spermanent or temporary password used by Remote PC's to access the HostUnit so as to prevent the unauthorized access of a Remote user to a HostPC, (18) terminating a Modem Linkage or Direct Line Linkage to a Host,(19) initiating a connection to another site, as required, (20) storingprocedures necessary to train a Host Unit to decode a particular HostPC's VDAC video raster output signal, so that such procedures can bereloaded by a Remote PC into the Host PC's memory to facilitate usingone Host Unit to access more than one Host PC without the need to repeaton-site training, and (21) exiting Remote PC application processing whenthere is no longer a need to access Host PCs.

A Host Unit can connect (via cable and adapters) to a Host PC and iscapable of (1) verifying a remote user's password entered to access theHost Unit, so that access to the Host PC will be denied in cases wherean invalid password is received; (2) permitting a Remote PC tooptionally take over the Host PC's keyboard and/or mouse by ignoring anyinput from the Host PC keyboard and/or mouse and accepting only keyboardand/or mouse input from the Remote PC's keyboard received through aModem Linkage or Direct Line Linkage; (3) permitting a user located at aHost site to take back control of a Host PC's keyboard and/or mouse bydepressing a momentary switch button on the Host Unit; (4) passingthough the Host PC's keyboard and/or mouse input signals to the Host PCvia input and output keyboard and/or mouse connectors on the Host Unit;(5) intercepting, storing, analyzing, decoding and then passing throughthe Host PC's VDAC video raster signal to the Host PC's VDM screendisplay via input and output video connectors on the Host Unit, even incases where a Remote PC is not accessing the Host unit; (6) decoding theHost PC's VDAC video raster output signals to either text or bit-mappedgraphics format; (7) identifying and storing, as necessary, VDAC datathat has changed between each VDAC refresh cycle; (8) compressing,transmitting and storing the changes in text or graphics data decodedfrom the VDAC raster output signal of the Host PC to a Remote PC; (9)supplying input/output interface cable receptacles to permit Host Unitsto be daisy chained with each other so as to allow a Remote PC to switchbetween, and remotely control, multiple Host PC's over a single phoneline and modem during a single phone call; (10) supplying AC power tothe Host PC, through an AC output connector, so as to permit the HostUnit, when desired, to temporarily cut power to a Host PC forcing theHost PC to reboot.

VDAC video raster output signals from a Host PC's VDAC circuits may varyfrom PC to PC (or adapter circuit to adapter circuit) making itimpossible to utilize a standard process to decode the signal. Duringinstallation of the Host Unit, software supplied with the apparatus maybe activated on the Host PC to train the Host Unit to properly decodethe text mode VDAC video raster output of the Host PC. During this onetime training process, predetermined text and character strings aredisplayed using software supplied with the Host Unit via the Host PC'sVDAC. The resulting video raster output signal of the PC's VDAC is thenanalyzed by the Host Unit's processors to determine the exact proceduresneeded to convert the VDAC raster output signals to known text data orgraphics pixel data displayed during the training process. The resultsof this training process yields the specific procedures and data neededto decode and capture text data or graphics pixel data from the VDACoutput of a specific PC. Such procedures and data are stored innon-volatile RAM contained in the Host Unit, so that the trainingprocess for a specific Host PC need not be repeated unless the Host PC'sVDAC is changed. This training process permits the Host Unit tointerface with any of the PC monochrome or color VDAC standards, such asCGA, EGA, or VGA familiar to persons in the trade. On request by aRemote PC said training procedures needed to decode a given Host PC'sVDAC signal may be copied to a file on a mass storage device connectedto the Remote PC. This procedure would then permit the Remote PC toreset the decode procedure used by a Host Unit to support situationswhere a single Host Unit at a site is switched between different PC's byuser's on site to facilitate remote diagnostics of a PC that has failed.

A less preferred embodiment of the present invention could be employedin which the video capture function of the Host Unit is accomplished byinserting an adapter card into one of the I/O buss adapter slots in thePC. This adapter card would have it's own microprocessor, or otherprocessing circuitry, that would independently capture and store a PC'sBasic Input Output System (BIOS) video data for transmission to the HostUnit over a cable interface from the adapter card to the Host Unit.There are several reasons why this embodiment of the present inventionis less preferred:

A. Many PC's now operate in a graphics VDM screen mode as opposed to atext VDM screen mode where data is displayed through the PC's internalBIOS (Basic Input/Output System) by setting pixels on a VDM screen asopposed to sending standard character format data to the VDM screen. TheWindows™ operating system developed by Microsoft Corporation is anexample of a such a graphics user interface software operating system.In a graphics VDM screen mode numerous VDM standards exist that definenumber, placement and intensity options available for displayinggraphics information on the VDM screen. Software drivers from thevarious PC application manufactures may modify or circumvent traditionalBIOS functions to display data on the VDM screen. As the result, theprocess of decoding graphics information at this level is morediversified and subject to more change than the preferred embodiment ofdecoding the actual VDAC video raster output signal which conforms to arelatively fixed standard (i.e. the input to a VDM).

B. Some PC's have motherboards with “built-in” video circuitry on themotherboard, which may not permit the user to disable video processingand/or may not pass video data across the PC's buss.

C. Inserting an adapter card into a PC requires shutting off the PC'spower then opening the PC to insert the adapter card. Such a procedureis not viewed as acceptable to the user as simply attaching interfacecables from the Host Unit to the VDAC interface port on the PC.Moreover, opening the PC to install the adapter card would make itdifficult and time consuming for unskilled personnel at an off-sitelocation to setup a spare Host Unit on a failed Host PC for remotediagnostic and/or repair by a off-site maintenance operation.

D. The size of the PC adapter card must remain within fixed size limits.Such limits could constrain the level of functionality that could beincorporated into the card.

E. The I/O buss adapter slot, power, etc. within the Host PC could failwhich would prevent the Host Unit from transferring any stored videodata from the Host PC.

F. An additional adapter card is required, which may preclude userswithout an available buss adapter slot from installing the apparatus.

A second less preferred embodiment similar to that discussed above,could be used where a dual function video I/O adapter card could beengineered and inserted in a PC's I/O buss adapter slot in place of thePC's existing video I/O board. One function of this adapter card wouldbe to provide video output to a VDM screen using standard videoconnector plugs. The other function of the adapter card would be capturethe video BIOS data using additional circuitry on the I/O adapter cardand transmit this data to a remote PC. In this case, the video adaptercard would conform to standard, pre-defined video display options andthereby avoid the different drivers and display approaches taken by thevarious video adapter card manufacturers. There are several reasons whythis preferred embodiment of the present invention is less preferred:

A. Inserting an I/O buss adapter card into a PC requires shutting offthe PC's power and then opening the PC to insert the card. Such aprocedure would not be as acceptable for the user as simply attachinginterface cables from the Host Unit to the VDAC interface port on thePC. Moreover, opening the PC to install the adapter card would make itdifficult and time consuming for unskilled personnel at an off sitelocation to setup a spare Host Unit on a failed Host PC for remotediagnostic and/or repair by a off site maintenance operation.

B. Some PC's have motherboards with “built-in” video circuitry on themotherboard, which may not permit the user to disable video processingand/or may not pass video data across the PC's buss.

C. The size of the adapter card must remain within fixed size limits.Such limits could constrain the level of features that could beincorporated into an adapter card with dual functionality.

D. The I/O buss adapter slot, power, etc. in the Host PC could failwhich would prevent the Host Unit from transferring any video data fromthe Host PC.

Other less preferred embodiments of the present invention could also beemployed where one, several, or all of the remaining functions of theHost Unit could be placed on one or more adapter cards using an approachsimilar to that discussed above for other less preferred embodiments ofthe present invention. For example, a special adapter cable could beconnected to the end of a keyboard cable's plug and plugged into aninput jack of a keyboard interface adapter card. Then, another adaptercable could be plugged into a output jack of the keyboard interfaceadapter card and the other end of the cable plugged into the normalinput keyboard plug on the PC. The keyboard adapter card would contain amicroprocessor and circuitry designed to perform the keyboard processingfunction described above for the Host Unit. There are several reasonswhy this preferred embodiment of the present invention is lesspreferred:

A. The multiple interface boards would be more costly to design andwould require the production of non-standard interface cables.

B. Some PC's have motherboards with “built-in” video circuitry on themotherboard, which may not permit the user to disable video processingand/or may not pass video data across the PC's buss.

C. Inserting an I/O buss adapter card into a PC requires shutting offthe PC's power and then opening the PC to insert the card. Such aprocedure would not be as acceptable for the user as simply attachinginterface cables from the Host Unit to the various interface ports onthe PC or on other Host Units. Moreover, opening the PC to install theadapter card would make it difficult and time consuming for unskilledpersonnel at an off site location to setup a spare Host Unit on a failedHost PC for remote diagnostic and/or repair by a off site maintenanceoperation.

D. The size of a adapter card must remain within strict size limits.Such limits could constrain the level of functionality that could beincorporated into the card.

E. Multiple adapter cards may be required, which may preclude users withinsufficient available buss adapter slots from installing the apparatus.

F. The I/O buss adapter slot, power, etc. in the Host PC could failwhich would prevent the functions now being performed by the Host Unitfrom being performed within the Host PC's adapter card(s).

From the above, it will be readily seen that one object of the presentinvention is to allow a user at a first location to view informationdisplayed on a video display terminal, or monitor, of a data processingdevice at second location.

Yet another object of the present invention is to allow a user to viewthe information on the video display terminal even if the dataprocessing device at the second location is locked up and no longerprocessing data or input commands.

A still further object of the present invention is to allow the user atthe first location to give commands to the data processing device at thesecond location in such a manner that the data processing deviceperceives the commands as coming from a standard input device typicallyattached to the data processing device such as a keyboard or mouse.

Another object of the present invention is provide for the temporaryinterruption of AC power to the data processing device at the secondlocation in response to a command from the user to force the dataprocessing device to initiate a cold boot, or power on routine.

Yet another object of the present invention is provide a system andmethod in which video display information contained in a video rastersignal output from a video display circuit of a data processing deviceis analyzed to determine the content of the signal and to convert thesignal into a form suitable for transmission over a standard publictelephone line or other communications network.

A still further objective of the present invention is to provide asystem and method for training the apparatus to recognize differentdisplay formats that are used to transmit information from a videodisplay circuit to a video display terminal or monitor.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings consist of 7 figures numbered 1 to 7. Figures that consistof more than one sheet contain a unique alphabetic suffix for eachsheet. When a figure is referred to in it's entirety, the alphabeticsuffix is omitted. A brief description of each figure is as follows:

FIG. 1 is a functional overview of the invention.

FIG. 2 is a front external view of the Host Unit.

FIG. 3 is a rear external view of the Host Unit.

FIGS. 4A-4P-5 are engineering diagrams representing an overview of theinternal circuitry of the Host Unit.

FIGS. 5A-5I-2 are block diagrams describing the microprocessor basedsoftware operating system controlling processing occurring in the HostUnit.

FIGS. 6A1-6D are block diagrams describing the process of training theHost Unit to recognize text for a specific PC.

FIGS. 7A-7G are block diagrams describing the software operating on theRemote PC.

FIGS. 8-A1 to 8-B-2 illustrate the current protocol used to communicatebetween a Remote PC and a Host Unit.

FIG. 9 illustrates an alternative embodiment of the present inventionimplemented on a circuit card suitable for insertion into a dataprocessing device.

The microfiche appendix, part 1 contains a detailed parts list of theparts presently included on the Host Unit's printed circuit board,cross-referenced to detailed electrical circuit schematics presentlyemployed within the Host Unit, which are provided as part 2 of themicrofiche appendix. Also, the microfiche appendix includes the detailedapplication and operating system software source code presently used forthe apparatus.

DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 is a operational overview of the invention. Rectangular objectson this diagram represent physical (i.e. hardware) components of theapparatus. Dashed rectangular boxes represent groupings of relatedhardware components at different locations, dashed lines representcables or cords, a solid line represents a communications interface(e.g. a telephone line or dedicated communications line), a arrow on theend of a line represents the direction that data or power flows and aline with no arrows indicates that data flows in both directions.

A PC located at a Remote Site 1 may be used to access a Host System 6.The Remote PC 2 may be equipped with a VDAC and monitor 3, a keyboard 4and a Hayes compatible Modem 5 familiar to persons in the trade toaccess a remote site via a Modem Linkage. No modem is necessary toaccess a Host Unit in cases where a Direct Line Linkage is used insteadof a Modem Linkage. A Mouse 4A may also be connected to the Remote PC.

Software installed in the Remote PC 2, permits the Remote PC to initiatea call via the Remote PC's Modem 5 to a Host Site's Modem 7 over astandard phone line or to make a direct linkage via a dedicated DirectLine Linkage. The apparatus currently supports up to 19.2 kb datatransfer rates between a Remote PC 1 and Host System 6 or between a HostUnit 8 and another Host Unit 13 or 18, but the speed of data transfercould be higher or lower and still fulfil the objects of the invention.

Host Units 8, 13, 18 may be daisy chained together to permit a Remote PCto switch between Host Units during a single access session. A group ofHost Units connected together on a single daisy chain is herein referredto as a “Host Site.” Software provided with the apparatus permits aRemote PC to access more than one Host Site, but, presently access toone Host site must be terminated before a different Host site may beaccessed.

Host Units 8, 13, 18 are identified by a unique number set by DIPswitches located in each Host Unit. There are a total of six DIPswitches in a Host Unit available to set a specific Host Unit ID number,so the Host Unit ID may be set by a user to yield a decimal numberbetween 00-63 depending on the positions of the switches. Of course,additional switches could be provided to allow for addressing of agreater number of Host Units. Presently, Host Unit 00 8 must beconnected to the Modem interface 7 via a modem cable from “Data In” 70(shown in FIG. 3) receptacle of the Host Unit to the serial interfacereceptacle on the modem or must have a Direct Line Linkage via adedicated cable from the “Data In” 70 (FIG. 3) receptacle of the HostUnit to a serial interface port on the Remote PC. An RJ-12 cable withserial port interface cable adapters can be used for either purpose.Although any suitable cable could be used, the RJ-12 cable has sixconductors, two of which are available for serial communications. OtherHost Units may then be connected in a Daisy Chain fashion using a cablefrom the “Data Out” 71 (FIG. 3) receptacle on the last Host Unit in theDaisy Chain 13 to the “Data In” 70 (FIG. 3) of the newly connected HostUnit 18. Host Units connected together in a daisy chain presently useRJ-12 cable for the connection from Host Unit to Host Unit, but anycable could be used with the appropriate conductors therein. In orderfor a Remote PC to communicate with a specific Host Unit on a daisychain, each Host Unit must have a unique ID number assigned from 01 to63. All data packets sent from the Remote PC to a particular Host Uniton a daisy chain use the Host Unit ID to address the transmitted datapacket to a specific Host Unit number for a response. Presently, aRemote PC may only access one Host Unit at a time, but may switch beenHost Units during a single active communications session.

A Host Unit 8 receives it's power from an AC electrical power source viaan AC power cord connected to an “AC Power” 61 (FIG. 3) receptacle onthe Host Unit. The Host Unit also supplies AC power to the Host PC 10 towhich it is connected through an AC power cord going from the “AC To PC”62 (FIG. 3) receptacle on the Host Unit to the AC power supply input onthe Host PC. By supplying power to the Host PC in this manner, AC powerto the Host PC may be temporarily cut by the Host Unit when instructedby a remote user's Remote PC to force a locked-up Host PC to cold-boot,so that normal Host PC processing can be restored remotely. This“cold-boot” procedure is particularly useful when the Host PC will nolonger respond to any keyboard or other input. The Host PC is turned offand back on by the remote user, thereby reinitializing the Host PC'sprocessing circuitry.

When a Host Unit 8 is first connected to a Host PC 10, the Host PC'skeyboard 11 is disconnected from the keyboard input jack and pluggedinto a “Keyboard Input From KB” 68 (FIG. 3) receptacle on the Host Unit.Then, a Keyboard Cable supplied with the apparatus is plugged into the“Keyboard Output To PC” 69 (FIG. 3) receptacle on the Host Unit and theother end of this cable is plugged into the keyboard input jack on theHost PC. In this manner, the keyboard's signals go through Host Unit tothe Host PC, which permits the Host Unit to interrupt Host keyboardsignals and redirect keyboard input to utilize the Remote PC's keyboardinstead of the Host PC's keyboard. Therefore, a Host PC need not have aKeyboard 11 present in order to facilitate Keyboard 4 data input andcontrol of the Host PC by a Remote PC. With regard to the Remote PC'sKeyboard 4, when the Remote PC 2 is accessing a Host Unit, the RemotePC's keyboard input is also captured by a software program running onthe Remote PC supplied with the apparatus and redirected out of theRemote PC to the Host Unit 8 for input into the Host PC 10 via either aModem (5 to 7) or Direct Line Linkage (2 to 8).

Similar to keyboard cabling, the Host PC's video cable from the HostPC's video display 9 (VDM) is disconnected from the Host PC's VDAC andplugged into either the Host Unit's 8 15 pin “VGA Out” 64 (FIG. 3) or 9pin “Video Out” 66 (FIG. 3) receptacle depending on the number of pinson the video cable's connector. Then, either the corresponding 9 pin or15 pin video cable supplied with the apparatus is plugged into theappropriate 15 pin “VGA In” 65 (FIG. 3) or 9 pin “Video In” 67 (FIG. 3)receptacle on the Host Unit 8 and the other end of the video cable isplugged into the Host PC's video display 9 (VDAC). This configurationallows the Host PC's video display 9 (VDAC) output signals, includingthe video raster signals, to pass through the Host Unit 8, so that theHost Unit can access, scan and decode the signals into either bit image,or monochrome or color text data and also store the most recent data (upto the internal storage capacity of the Host Unit) for transmission to aRemote PC when requested.

A serial cable can be connected from one of the Host PC's communicationsports to a “Serial” 72 (FIG. 3) receptacle on the Host Unit 8. Thisconnection permits data file transfers to occur between a mass storagedevice on a Remote PC 2 and the Host PC 10. This connection also permitsdata from a Remote PC's Mouse 4A to be transmitted to the Host PC'sserial port through the Host Unit's Serial 72 (FIG. 3) interface. Mouseinput 4A from a Remote PC is captured by software running on the RemotePC (supplied with the apparatus) and redirected out of the Remote PC 2to the Host Unit 8 for input into the Host PC 10.

When a Host Unit 8 is first connected to a Host PC 10, the Host PC'sserial Mouse 11A (if present) is disconnected from the Host PC's serialport and plugged into a “Mouse” 73 (FIG. 3) receptacle on the Host Unit.This permits Mouse 11A signals to pass through Host Unit to the Host PCvia the “Serial” 72 (FIG. 3) port interface on the Host Unit 8. Thisapproach permits the Host Unit 8 to interrupt any Host PC Mouse 11Ainput signals and redirect mouse data input to utilize the Remote PC'sMouse 4A instead of the Host PC's Mouse 11A. On this basis, a Host PCneed not have a Mouse 11A present in order to facilitate Mouse 4A datainput and control of the Host PC by a Remote PC. A mouse interface couldexist on any Host Unit on a daisy chain (e.g. Host Unit 01 13, Unit.,18, etc.).

A microprocessor and software located in each Host Unit on a daisy chain8, 13, 18 looks for communication data packets sent from a Remote PCaddressed individually to the Host Unit's ID number. When received,codes contained in the data packet define the nature of a Remote PC'sprocessing request. For example, a data packet may contain a coderequesting the Host Unit to verify that a password contained in thepacket is correct. If the password is correct, the Host Unit transmits adata packet back to the Remote PC with a code indicating the passwordhad been verified. Otherwise, a data packet containing a code indicatingthat the password was incorrect is returned to the Remote PC. Similardata packet requests and responses would be sent over the communicationline interfaces for other remaining functions of the system.

A second microprocessor, memory storage and software also exists in eachHost Unit. The primary purpose of this microprocessor and relatedoperating system software is to capture, decode, store and transmitindividual Host PC VDAC data to a Remote PC. Although the most preferredembodiment of present invention contains two microprocessors to handlethe video analysis and the communications with a remote PC, it iscontemplated that these functions could be performed by a singlemicroprocessor having sufficient computing power to conduct bothoperations. Notably, as microprocessor technology continues to evolve,it is possible that a single processor system could be developed,thereby increasing reliability and reducing costs.

Host System 01 12 and Host System 17 represent examples of how otherHost Unit/Host PC configurations can be daisy chained at a site, so thatone Modem or Direct Line Linkage could be used to permit a Remote PC toswitch between multiple Host Units during a single communicationssession. The “..” in the “Unit..” and “Host System..” identifiers onFIG. 1 are used to indicate one or more additional Host Units may existon the daisy chain. The maximum number of Host Units depends on theavailable number of bits used for each Host Unit address, and the mostpreferred embodiment supports up to 64 Host Units at any one Host Site.These other Host System configurations are connected to their respectiveHost PCs in the same manner as described above for Host Unit 00 8. Morespecifically, Host Unit 01 13 and Host Unit, 18 are connected to videodisplays 15, 19; Host PCs 16, 20; and Keyboards 17, 21 using the sameprocedures described for Host Unit 00 8 above, except the last Host Unitin the daisy chain would not have a daisy chain cable connected to theHost Unit's “Data Out” 71 (FIG. 3) receptacle. Software installed on aRemote PC (provided with the apparatus) permits a Remote PC to accessmore than one Host Site, but access to one Host site must be endedbefore access to another Host site can begin (i.e. no more than one HostSite may be accessed at a time).

FIG. 2 details a frontal view of a Host Unit. The front panel of theHost Unit includes five status indicator lights 50-54 and an “Action”momentary switch 55. All five indicator lights will be off until theON/OFF power switch, located on the right rear side of the Host Unit isturned ON.

A detailed description of the purpose of each of the five indicatorlights going from left to right is as follows:

-   -   AC Power 50—This light indicates that the Host Unit's on/off        switch is in the “on” position and AC power is being received        into the Host Unit.    -   Keyboard Local 51—This light indicates the keyboard/mouse        attached to the Host Unit is available for use.    -   Keyboard Remote 52—This light indicates a remote user is        accessing the Host Unit. If the light is blinking, it means a        remote user is in the process of connecting to the Host Unit or        has been previously blocked by a Host PC user from taking over        the keyboard. If the light is ON, it means a remote user has        taken over the Host PC's keyboard and/or mouse.    -   Daisy Chain 53—This light presently blinks periodically        indicating a remote user is currently connected to one of the        Host Unit's on the daisy chain. If no remote user is accessing a        Host Unit on the daisy chain, the light will be off.    -   Setup Mode 54—This light blinks during the initial training or        re-configuration of the Host Unit to indicate the Host Unit is        properly linked to the Host PC. This light also blinks when file        transfers are occurring between a Remote PC and Host PC.

If someone is using a Host PC's keyboard and/or mouse when a Remote PCattempts to take over the Host PC, a user at a Host PC site may wish toretain control of the Host PC's keyboard and/or mouse by depressing theAction 55 momentary switch. Only one user can have control of the HostPC's keyboard and/or mouse at any point in time. In cases of conflict,the user at the Host site has the final authority to determine whocontrols the Host system's keyboard and/or mouse. Control may be passedback and forth by depressing the Action 55 momentary switch. Regardlessof who has current control of the Host Unit's keyboard and/or mouse, aremote user will have the ability to view the Host PC's VDM screenremotely on their Remote PC after they have successfully connected to aHost Unit. Such VDM screen access can be prevented by a Host user byturning the Host Unit's ON/OFF switch OFF.

As previously mentioned, the Keyboard Remote 52 light on the front ofthe Host Unit indicates a remote user is accessing the Host Unit. If thelight is blinking, it means a Remote PC is in the process of initiallyaccessing the Host Unit or has been previously blocked by a Host PC userfrom taking over the Host PC's keyboard. If the light is ON, it means aremote user has taken over the Host PC's keyboard and/or mouse. When aremote user initially attempts to take over a Host PC, a brief audiblealarm sound is generated from a speaker (not shown) within the Host Unitto further alert anyone present at the Host Site that the Host Unit'skeyboard and/or mouse is about to be taken over by a Remote PC.

While the Keyboard Remote 52 light is flashing, another user at the HostPC may depress the Action 55 momentary switch on the front panel toprevent a Remote PC from taking over the Host PC's keyboard and/ormouse. If the Action 55 momentary switch is depressed for this purpose,the Keyboard Remote 52 light will continue to flash and the remote userwill be prevented from taking over the Host PC's keyboard and/or mouseuntil either the Action 55 momentary switch is depressed again or theremote user disconnects and re-connects at a later time. If the remoteuser should disconnect from the Host Unit while the Keyboard Remote 52indicator is flashing, the indicator will turn off automatically. When aremote user is blocked from accessing a Host Unit's keyboard and/ormouse, they will receive an alert message on their VDM screen (connectedto the Remote PC) during the connection process. Even if a Remote useris prevented from accessing the keyboard and/or mouse by persons presentat the Host Unit, the remote user will still be able to monitor any VDMscreen activity on the Host PC. Once a user has taken over a Hostkeyboard, the Keyboard Remote 52 indicator light will remain on. Theremote user's privilege to continue to use the Host PC's keyboard andmouse can be revoked at any time by depressing the Action 55 momentaryswitch on the front of the Host Unit, which causes the Keyboard Remoteindicator light to blink until the remote user disconnects from the HostUnit. When such an action is taken, the remote user will remain lockedout until either the Action 55 momentary switch is depressed again orthe remote user terminates the connection and reconnects at a latertime.

In cases where a Remote User desires access to a Host Unit in a mannerthat would not be readily detectable by anyone using the Host PC(hereinafter referred to as a “stealth mode”), the embodiment of theHost Unit could only include AC Power 50 and Setup Mode 54 lights andwould not include the audible alarm. In such cases, the Remote userwould access the Host Unit in a “view only” mode, as more fullydescribed below in the narrative supporting FIG. 5B. This embodimentwould be used, for example, in cases where an employer desired toremotely, discreetly, monitor employee use of an employer's Host PC.

FIG. 3 details the present rear view of the Host Unit. A variety ofalternative interface cables, adapters and connectors could have beenused to connect the Host Unit to the Host PC, modem (Modem Linkagemode), Remote PC (Direct Line Linkage mode), and/or another Host Unit ona daisy chain. For example, the R J-12 receptacle presently used toconnect the Host Unit's serial output to the Host PC's serial inputcould have used a 25 pin female receptacle and a parallel interfacecable from the Host Unit to one of the parallel ports on the Host PC. Asa second example, standard serial cables and serial receptacles couldhave been used in place of the RJ-12 receptacles to connect the HostUnit to a modem/Remote PC and to connect Host Units together on a daisychain. Such alternative cabling, connector and receptacle approaches areknown to persons familiar with the trade and do not materially affectthe functioning of the apparatus.

The rear panel of the Host Unit presently contains the AC powerreceptacles, various RJ-12 data transfer linkage jacks, various videointerface receptacles, keyboard interface ports, optional mouseinterface ports and user replaceable fuse with a fuse blown indicatorlight. A detailed description of each item on the back panel going fromleft to right is as follows:

-   -   ON/OFF Switch 60—The ON/OFF power switch 60 is used to turn off        AC power input into the Host Unit. Turning this switch ON or OFF        controls only power flowing to the internal circuitry of the        Host Unit and has no effect on AC power flowing to the Host PC.    -   AC Power 61—The female end of the AC power cord used that is        normally used by the Host PC to obtain AC power is plugged into        this receptacle and the other three-prong male end of the cord        is plugged into a source for AC power such as a public utility        wall outlet or a battery backup system. This cord would then        carry AC power into the Host Unit.    -   AC To PC 62—One end of the AC power cord supplied with the        apparatus is plugged into this receptacle and the other end of        the power cord is plugged into the AC power input of the Host        PC, so that the Host PC depends on the Host Unit for it's AC        power. This approach permits the Host Unit to satisfy a request        to cold-boot the Host PC by temporarily cutting off AC power to        the Host PC. The power can be interrupted for any suitable time        to allow the Host PC to properly re-boot, for example from        approximately 1 to 30 seconds. In the preferred embodiment this        time is approximately 15 seconds.    -   Fuse 63—The system employs a user replaceable 5 amp/250 volt        fuse on the rear panel with an indicator light which lights when        the fuse is blown. When the fuse is blown power to the Host PC        will be terminated.    -   Fuse Light 63A—When AC power is applied to the Host Unit and the        Fuse 63 is blown, this indicator light will be ON.    -   VGA Out 64—For Host PC's with a VGA graphics VDAC, the 15 pin        connector from the end of the Host PC's VDM cable is plugged        into this receptacle. This receptacle permits the signal        received from Host PC's VDAC through the VGA In 65 receptacle to        be passed out to the Host PC's VDM.    -   VGA In 65—For Host PC's with a VGA mode VDAC, one end of the 15        pin male to male VGA video interface cable (supplied as part of        the apparatus) is plugged into this receptacle and the other end        of the cable is plugged into the Host PC's VDAC receptacle. This        cable interface permits the Host Unit to capture the video        output signal from the Host PC's VDAC and pass the signal out        through the VGA Out 64 receptacle to the Host PC's VDM.    -   Video Out 66—For Host PC's with other than a VGA graphics card,        the 9 pin connector from the end of the Host PC's video monitor        cable is plugged into this receptacle. This receptacle permits        the signal received from Host PC's VDAC through the Video In 67        receptacle to be passed out to the Host PC's VDM.    -   Video In 67—For Host PC's with other than VGA mode VDACs, the        female end of the 9 pin female to male video interface cable        (supplied as part of the apparatus) is plugged into this        receptacle and the other male end of the cable is plugged into        the Host PC's VDAC receptacle. This cable interface permits the        Host Unit to capture the video output signal from the Host PC's        VDAC and pass the signal out through the Video Out 66 receptacle        to the Host PC's VDM.    -   Keyboard Input From KB 68—The Host PC's keyboard cable is        plugged into the Keyboard Input From KB receptacle instead of        into the PC's keyboard input receptacle. This permits the Host        Unit to pass or block any Host keyboard input to the Host PC, as        required.    -   Keyboard Output To PC 69—One end of the male to male keyboard        interface cable (supplied as part of the apparatus) is plugged        into this receptacle and the other end of the cable is plugged        into the Host PC's keyboard input receptacle. This receptacle is        used by the Host Unit to transfer keyboard input from either the        Remote or the Host PC's keyboard to the Host PC.    -   Data In 70—One end of a telephone style RJ-12 (6 wire) cable        (supplied as part of the apparatus) is plugged into this        receptacle and the RJ-12 jack on the other end of the cable is        connected to either the Data Out 71 jack of another Host Unit or        to either (1) an external, stand alone, Hayes compatible modem        for a Modem Linkage mode or (2) a Remote PC's data transfer        interface port for a Direct Line Linkage mode. When a Host Unit        is connected to another Host Unit via a daisy chain, at least        one of the Host Units on a daisy chain must be connected to a        modem (Modem linkage mode) or directly connected to a Remote PC        (Direct Line Linkage mode). The modem connection can be        accomplished by plugging the open end of the telephone cable        into the telephone jack-to-9 pin male adapter plug (supplied        with the apparatus), and then plugging the 9 pin male adapter        into the data interface receptacle on the modem. If the modem        has other than a female 9 pin receptacle, then gender changers        and/or 9 pin to 25 pin adapters (available for the apparatus)        must be used to complete the Unit-to-modem connection. The        Remote PC Direct Line Linkage connection can be accomplished by        plugging the open end of the telephone cable into the telephone        jack-to-9 pin female adapter plug (supplied with the apparatus),        and then plugging the female adapter into the data interface        receptacle on the Remote PC. If the Remote PC has other than a        male 9 pin data interface receptacle, then gender changers        and/or 9 pin to 25 pin adapters (available for the apparatus)        must be used to complete the Unit-to-Remote PC connection.    -   Data Out 71—One end of a telephone style RJ-12 (6 wire) cable        (supplied as part of the apparatus) is plugged into this        receptacle and the other end of the RJ-12 cable is plugged into        the Data In 70 receptacle of another Host Unit. If this is the        last Host Unit in a daisy chain, no cable would be plugged into        this receptacle. When a Host Unit is connected to another Host        Unit, at least one of the Host Units on a daisy chain must be        connected to a modem for the Modem Linkage mode or to a Remote        PC for the Direct Line Linkage mode (as described above for the        Data In 70 receptacle); The Data In 70 and Data Out 71        receptacles are also used to transmit data packets between a        selected Host Unit and a Remote PC.    -   Serial 72—One end of an RJ-12 cable supplied with the apparatus        is plugged into this receptacle and the other end of the RJ-12        cable is plugged into a serial communications port on the Host        PC using a RJ-12 to serial port adapter plug provided with the        apparatus. Data file transfer between the Host PC and Remote PC        occur through this Serial 72 receptacle. Presently, the        apparatus uses serial data transfers but transfers are also        possible through the Host PC's parallel port.    -   Mouse 73—The Host PC's serial mouse cable is plugged into the        male Mouse receptacle 73 instead of into the PC's serial port.        This permits the Host Unit to pass through or block any Host        Mouse input to the Host PC, as required.    -   Aux 74—Auxiliary devices may be plugged into this receptacle,        which is presently an RJ-12 jack, and this receptacle permits        two way communications between the device and the Host Unit.        Specific uses for this port are discussed later.

On the side of the Host Unit there are eight DIP switches (not shown).The left most 6 DIP switches indicate the Host Unit's ID number. Whenthese 6 DIP switches are in the down position, the Host Unit isconnected directly to a modem (Modem Linkage mode) or to a Remote PC(Direct Line Linkage mode). Otherwise, when the Host Unit is daisychained through other Host Units, each Host Unit on the daisy chain mustbe assigned a unique DIP switch setting indicating an address from 1 to63 by the user. On this basis, only a maximum of 64 Host Units can bedaisy chained at a Host Site. As noted above, however, the number of DIPswitches could be increased to allow additional units to be daisychained together. The 6 DIP switch settings presently represent binaryvalues reading from left to right. Accordingly, if only the left mostDIP switch is set to the up position, the Host Unit's ID would be 1. Ifthe left most two DIP switches were set to the up position, the HostUnit's ID would be 3, (i.e. 1+2) and so forth. In order to remotelyaccess a Host Unit, the Host Unit ID number must be correctly defined onthe remote PC's call table, as discussed below under the narrative forFIG. 7.

The seventh and eighth DIP switch are accessible to the Host Unitcircuitry. The seventh DIP switch is not presently used. The eighth DIPswitch is presently used for VGA VDAC's to indicate whether a monochrome(i.e. DIP switch in the UP position) or color (i.e. DIP switch in theDOWN position) VGA VDM is connected to the VGA OUT 64 receptacle of theHost Unit.

FIG. 4A through FIG. 4P illustrate general functional diagrams of theHost Unit's internal circuitry. A detailed list of specific electroniccomponents presently installed in the Host Unit is contained in themicrofiche appendix, part 1. Detailed circuit diagrams defining thespecific internal circuit layouts for the present embodiment of the HostUnit is also contained in the microfiche appendix, part 2.

FIG. 4A depicts an overview of the Host Unit's circuitry. The unitcontains a power supply 100, two microprocessors (CPUs) 106, 114, andassociated circuitry.

The Video CPU 114 controls the video circuitry (i.e. blocks 110-113 and115), interface to the Host PC's Data Circuitry 116, and interface tothe Host PC's Mouse Circuitry 117. The Host Data 116 and Mouse Circuitry117 interfaces between the Host Unit and Host PC occur using the HostPC's serial interface port. However, other Host PC data ports, such as aparallel interface port, could have been chosen for this purpose. TheHost Data Circuitry 116 interface is used to accomplish file transfersbetween a Remote PC and a Host PC.

The software program source code for the apparatus is set forth in themicrofiche appendix. Additional features of the invention discussedbelow that could be included in the software shown in the appendix byone of skill the art include mouse processing capability, Host PC screenhistory recordation, files transfers between a Host PC and Remote PC,password lockout protection, temporary password processing, trainingparameter up-loading and down-loading, internal modem operation,acoustical coupler operation, and AUX port operation.

The Control CPU 106 controls the Keyboard Circuitry 101, Host Unit FrontPanel Circuitry 102 and Remote Data Circuitry 103. The KeyboardCircuitry 101 passes the Host PC's keyboard signals through to the HostPC or alternatively redirects all keyboard signals away from the HostPC's keyboard to a Remote PC's keyboard (via the Remote Data Circuitry103) when requested by an authorized remote user. The front panelcircuitry controls the indicator lights and action button located on theHost Unit's front panel (see FIG. 2) as well as the Host Unit's audiblealarm. The Remote Data Circuitry 103 permits digital data to flowbetween the Host Unit and a Remote PC and/or other Host Units on adaisy-chain. This digital data could be transmitted using RS-232 serialcommunication signals familiar to persons in the trade. This digitaldata could include, for example, video display data being transmittedfrom a Host Unit to a Remote PC, Keyboard input data transmitted fromthe Remote PC to a Host Unit and modem setup strings. Also, the ControlCPU 106 has access to the Host Unit's fixed serial number 104 andNon-Volatile (NV RAM) memory 108. NV RAM 108 is used to store thecritical data needed to be saved in cases where AC power to the HostUnit is interrupted, such as, for example, the password(s) needed toaccess the Unit.

The Control CPU 106 and Video CPU 114 communicate with each other via atwo-way data port 107.

Presently, the power supply 100 is a linear power supply with powertransformer, bridge rectifier, filter capacitor, and two 7805 5 voltregulators. The power control circuitry controls AC power to the Host PCand in the present implementation is comprised of a 5 amp fuse, 5 amprelay and associated driver transistor. The driver transistor iscontrolled by a power lock circuit 105 that prevents inadvertentactivation of this circuit, which would cause AC power to the Host PC tobe temporarily interrupted.

The Keyboard Circuitry 101 interfaces to the Host PC and it's keyboard.Referring to FIG. 4B, the Host keyboard signals 122 are comprised of twoprimary lines: CLOCK and DATA which allow bi-directional communicationbetween the keyboard and the Host PC 120. Symbols used on FIG. 4B todenote switches, number of lines, etc. are familiar to persons in thetrade. When remote access is not occurring to a Host Unit (i.e. a normallocal operating mode), the Host PC's keyboard signals are routeddirectly to the Host PC's keyboard input receptacle as shown in block121. When in remote mode (i.e. a remote user has taken control of a HostPC's keyboard input), the Control CPU 106 causes the circuitry 121 todisconnect the Host PC's keyboard 120 and causes the Host PC to receiveit's keyboard signals from the Control CPU via references 123, 124, 125.The two keyboard signals, Clock and Data, (nominally at 5 volts, pulledhigh via resistors) go through an I/O circuit 124 and 125 whichseparates them into Input and Output lines for each signal 126 and shownin more detail at block 127. This circuit contains an open collectorgate 142 and a pull-up resister 141 (a nominal 2.2K value was used).This allows the Host Unit to emulate a keyboard signal. References 143and 144 represent how the clock and data signals are split into inputand output lines connected to the control CPU.

The Mouse circuitry 117 (FIG. 4A) is further detailed in block 131 onFIG. 4B. In local mode, the serial mouse signals 132, which could use anRS-232C protocol, are passed from the Mouse interface connector (seeFIG. 3 at reference 73) directly through to the Host Unit's serialoutput (see FIG. 3 at reference 72) to the Host PC's serial data port130, as shown. When in remote mode, the Host Unit's Video CPU 114activates a switch so that only mouse input data received from theRemote PC 133 is passed through to the Host PC's serial port. Inaddition, this connection also serves another purpose. It allows datafiles to be transferred between the Host PC and Remote PC. The decisionas to whether mouse data or data files are being transferred isdetermined by the software operating system on the Remote and/or HostPC's. The Host PC treats all serial input received as mouse data unlessa special software program, provided as part of the apparatus, isactivated on the Host PC (via Keyboard commands from the Remote PC)which will cause the Host PC to treat serial input data as data filetransfers instead of mouse input data. When processing by this softwareprogram is complete, the Host PC will treat any subsequent serial inputas mouse data.

Host units can be connected together as a daisy-chain using a dedicatedcable to interconnect each Host Unit. A modem (or primary serial dataline) connects to the Host Unit Data In receptacle of the Host Unitnumber 00 and the Data Out port of this Host Unit can then be connectedto the Data In receptacle of another Host Unit, and so on as previouslydescribed in the narrative for FIG. 1.

The Control CPU 106 contains an 80C32 microprocessor, 32K of RAM memoryand 32K of EPROM memory, but any microprocessor and any amount of memorycould be used with the invention. The EPROM contains the operatingsystem software for this CPU. Also, the Control CPU 106 has access to an8 position dip-switch. As discussed above, this dip-switch determinesthe unit's identification number. This number, or address, is used toallow access to a particular Host Unit on a daisy-chain by a Remote PC,and addresses may be determined by the user. However, Host Unit number00 is different and expects a Hayes compatible modem, or Direct LineLinkage to be connected to the Data In port (see FIG. 3 at reference70).

As shown in FIG. 4C, the Remote Data Circuitry 103 allows Host Unitaccess to occur. Data coming from the Remote PC 150, electrically passesthrough the Data In port to the Data Out ports of each Host Unit 151,152, 153 on a daisy chain. The Control CPU 151A, 152A, 153A of each HostUnit receives any data passing through the daisy-chain from the RemotePC 150 on a Receive 155 line.

Data going from Host Units to a Remote PC is on a different transmissionline 156 which is separate from the Receive 155 line. When no Host Uniton a daisy-chain is accessed none of the Host Units are electricallyconnected to the transmission 156 line. However, when a Remote PCaccesses a Host Unit via the receive 155 line, that Host Unitelectrically connects to the transmission 156 line through a relay 151B,152B, 153B to facilitate two way communication between the Host Unit anda Remote PC.

AC Power to the Host PC is controlled by a power lock circuit 105 (FIG.4A). This circuit insures that an intentional data transfer occursbefore the power control circuitry 100 will briefly interrupt AC powerto the Host PC. This “lock” circuitry requires that not only a specificseries of values be written to it, but also at specific port addresses,and a separate bit value must be correct at the time of writing, beforethe Host Unit will permit AC power to the Host PC to be interrupted.This power lock circuit, as well as the video processing circuitrydiscussed below, both utilize a Cyclic Redundancy Check (CRC) functionfamiliar to person of skill in the art for processing.

As shown in FIG. 4D, CRC is a common process used for generatingpseudo-random numbers and reducing long streams of data to a smallercheck sum quantity (1, 2, or more bytes). CRC is typically used forrandom number generation, bit stream identification and bit stream errordetection.

The CRC process is based on shifting the parity, or single bit sum, ofan input data signal 185 and selected bits 178, 179, 181 of a shiftregister output 177. Each time the shift register 172 is clocked 171, anew bit 170 is shifted into the shift register. EXCLUSIVE OR gates 180,182, 184 generate the parity signal. After 8 clocks, the new value 177will have no apparent relation to the previous value. If the input bit185 is hard-wired to plus (or a logical 1), a long series ofpseudo-random values can be generated. Rather than hard-wiring thisinput 185, gate 184 would normally be omitted and signal 183 would beconnected to 170. The series generated will repeat every N clock cycleswhere N has a theoretical maximum of 256 for an 8 bit shift register and65,536 for a 16 bit shift register. If a data stream is present 185,this will modify the pseudo-random series and produce a unique value at177 which can be used to identify the data stream. Note that theparticular bits 173, 174, 176 of the shift register output 174 selectedfor parity generation determines the pseudo-random series generated.That is, connections 178 and 179 can be connected to different bits of177, such as the output bit referenced at 175 and/or more bits can beadded with more EXCLUSIVE OR gates and the numbers; generated will bedifferent.

FIG. 4E shows a diagram of the power lock circuitry. The CRC generator213 uses an 8 bit shift register and is similar to FIG. 4D with the datainput 185 omitted and a clear input 212 is provided. This clear inputwill set the CRC value to zero. Power to the Host PC is terminated whenbit latch output 222 is ON. To set this bit latch output 222, theControl CPU (in the present implementation.) generates a write pulse tothe bit latch 221 when the digital signal 223 is a one (logical high).This signal 223 is a one (logical high) only when the CRC value 196 iscompared via the compare circuitry 198 and is equal to the value 128(hexadecimal 80) which is hard-wired 197 to this value. Signal 202 willclock the CRC generator 213 only when the compare output signal 190 is aone (logical high). Otherwise signal 202 will instead set the CRC value196 to zero. This is accomplished by logic gates 200, 204, 205. When aCRC output 196 is compared with data input 194 via compare circuit 195,and is equal, then output 190 will be a one (logical high). Assuming theCRC value 196 is zero, then approximately 250 clock pulses 211 occurbefore the CRC value 196 will reach 128 (80 hexadecimal) during whichtime the CRC generator 213 will have produced approximately 250 uniqueCRC values 196. To produce these clock pulses 211 the value 194 must beequal to the current CRC value 196 for each write pulse 202. This databyte input 194 is composed of three sets of signals 191, 192, 193. Theaddress lines 193 makes this port 194 appear as 8 output ports to theControl CPU 106 (FIG. 4A). Thus, the Control CPU must correctly set upthe lock bit 191, and write (via pulsing at reference 202) a correctvalue 192 to the correct port 193 with the combination of these signalsbeing equal to the current CRC 196 to clock 211 the CRC generator andget the next CRC value. This continues until the CRC value becomes 128(80 hexadecimal) and then the Control CPU pulses 220. The choice of 191,192, 192 ensures that the Host PC's AC power will not be interruptedinadvertently in the event of erroneous processing by the Control CPU.

The above circuit is employed in the most preferred embodiment of thepresent invention to ensure that power to the Host PC will not beinterrupted unless commanded by a user. However, if such precautions arenot warranted, a simpler power management circuit could be employed to,for example, reduce the overall cost of the system. This circuit could,for example, only require that the control CPU 106 receive a powerinterrupt command byte from the remote user. Other examples of lesscomplex power management circuits will be readily apparent to those ofskill in the art in light of the above discussion.

The Control CPU 106 has access to a serial number device 104. Thisprovides a unique hardware serial number for the unit. The preferredembodiment of the present invention uses a DALLAS DS2401 part, whichcomes pre-programmed with a unique serial number. Of course, othersuitable means could be employed to retain the hardware serial numberfor each Host Unit. Also, the Host Unit includes 2K of non-volatile RAM108 for storage of the unit's password and video timing and CRCinformation peculiar to the Host PC's video hardware configuration,which are determined during a Host Unit training process discussed belowin connection with FIGS. 6A to 6D.

In the preferred embodiment, the Video CPU 114 contains an 80C32microprocessor, two banks of 32K by 8 bits of RAM memory (totaling 64K)and 32K of EPROM memory. This microprocessor, as well as the controlmicroprocessor 106 discussed above, could be replaced by any suitablemicroprocessor (for example an 80286, 80386, 80486, 68000, 68010, etc.)and memory. The EPROM contains the operating system software for thisCPU. An RS-232C serial port 116 is provided for file transfers or serialmouse data to the Host PC.

The portions of the Host Unit which deal with video processing employ acombined hardware/software approach. In this regard, discrete logiccircuitry does some of the video processing and a microprocessor andassociated operating software performs the remainder of the videoprocessing. In the preferred embodiment, this was done to preserveflexibility in the video processing techniques. As will be readilyapparent to those of skill in the art, other embodiments of theinvention may dedicate more of this processing to discrete circuitry, tolessen demands placed on the processing software to increase processingperformance, or more of this processing to software or hardware toenhance flexibility.

The Control CPU 106 and the Video CPU 114 communicate through a two-waycommunication port 107. As shown in FIG. 4F, the Control CPU 106 checksthe write status 232 to see if the latch 234 is empty. If it is empty,the CPU presents a value 230 and toggles the write line 231. This willset the bit latch 236 and the status 232 will indicate that the latch234 is full. The Video CPU 114 can then poll the read status 232 and, ifit is set, read the value 233 by pulsing 235, which will reset the readstatus 232. The Video CPU 114 checks the write status 240 to see if thelatch 245 is empty. If it is empty, then the Video CPU 114 presents avalue 246 and toggles the write line 244. This will set the bit latch243 and the status 240 will indicate that the latch 245 is full. TheControl CPU 106 can then poll the read status 240 and, if it is set,read the value 242 by pulsing 241, which will reset the read status 240.The status signals 232 and 240 are both referenced as read and writestatus and their function depends on which CPU is polling the statussignal.

As shown in FIG. 4A, the Video CPU 114 programs the video circuits 110,112, 113 after which video signals, including video raster signals,coming from the Host PC VDAC (discussed in more detail in FIG. 4G) areprocessed by the Video Signal Input Circuitry 110 and the Video CPU 111.The resulting video data is written to the Video Output Buffer 115. Inthe preferred embodiment, this buffer is 32K by 16 bits, which is enoughmemory to hold one screen of 800 by 600 digitized graphics or more thanone screen of text data. The Video Processor 111 writes to this VideoOutput Buffer 115, so that the data written to the buffer can be read bythe Video CPU 114.

The video input enters from the Host PC's VDAC, through a videointerface cable which is presently either a DB 9 pin receptacle (withTTL video signals) or a DB 15 pin receptacle (with analog video signals)located on the rear panel of the Host Unit (see FIG. 3 at references 65or 67). For both of these receptacles, the horizontal and vertical syncsare TTL signals. When these video signals enter the Video Signal InputCircuitry 110, the circuitry selects sync polarity, TTL or analog mode,and a particular color signal. This signal is passed to the VideoProcessor 111.

Analog VGA display monitors can be either color or monochrome. Aspreviously mentioned the eighth DIP switch in the Host Unit is presentlyused to indicate whether a monochrome (i.e. DIP switch in the UPposition) or color (i.e. DIP switch in the DOWN position) VGA VDM isconnected to the VGA OUT 64 receptacle of the Host Unit.

Analog (VGA) monochrome monitors generally display only the greensignal. When the PC is reset, the VDAC will interrogate the threemonitor identification signals coming from the VDM to determine the typeof monitor that is connected (i.e. monochrome or color). If a monochromemonitor is detected, the VDAC will add together the red, green, and bluecolor signals and output this one combined signal to all three color gunoutputs. This gray scale summing is designed so that the same amount ofbrightness will be displayed in monochrome as would be displayed incolor.

The three monitor identification signals appear on pins 4, 11, and 12 ofthe monitor's DB15 video connector. The Host Unit currently hardwiresthese signals so as to appear to the VDAC that a color monitor is alwayspresent (i.e. pins 4 and 11 grounded, pin 12 open), regardless if amonochrome or color VDM is connected to the VGA OUT 64 receptacle of theHost Unit. For simplicity, this enhancement to the Host Unit's circuitryis not reflected in the schematics contained in the microfiche appendix,part 2.

If a color monitor is connected to the Host Unit, the red, green, andblue signals simply pass through, and are displayed in color. When amonochrome display is attached, the Host Unit will apply gray scalesumming and output this sum on the red, green, and blue signals going tothe display monitor. This summing is not reflected in the microficheappendix. The formula for gray scale summing is: 30% red+59% green+11%blue. This gray scale summing is independent of the Host Unit's videoprocessing and affects only the video output to the monochrome monitor.The Host Unit could determine whether or not to apply this gray scalesumming by examining the identification signals coming from the monitor,but in the current implementation, position 8 of the Dip Switch is usedto indicate the type of VDM connected to the Host Unit.

Forcing the Host PC's VDAC to believe a color VDM is always connectedpermits the Host Unit, and remote users, to have access to colorinformation, regardless of the monitor type connected to the Host PC viathe Host Unit. In other words, this approach permits a remote user toview a Host PC's VDAC in color even in cases where a monochrome VDM isconnected to the Host Unit. In addition, because Host Unit video outputsignals are buffered, the Host Unit need not have a VDM connected to theHost Unit. In cases where a remote user has a monochrome VDM connectedto their Remote PC, the TVLINK.EXE software program (discussed later)will ignore any color attributes sent by the Host Unit for displaypurposes.

An overview of the color signal selection circuitry of the Video SignalInput Circuitry 110 is found in FIG. 4G. Video Select Latch 257 controlswhich color signal is selected. This latch is set by the Video CPU 114.Latch signals 256 control the multiplexer in the Video Signal Select 264which selects one of the TTL signals red 260, green 261, blue 262, orintensity 263, or the converted analog signal 254 and presents thissignal at 265 which will be clocked into the bit latch 267 for eachpixel clock 266 and appear at the Bit Latch output 268. The VGA ColorSelect 255 signal causes the Analog to TTL Circuitry 253 to select aparticular analog signal (i.e. red 250, green 251, or blue) 252, to beconverted to a TTL output 254.

The most preferred embodiment of the invention presently provides foronly one color signal to be processed per video raster scan cycle.Therefore, multiple scan cycles are required to derive color textinformation. Since approximately 60 scan cycles occur per second, colorsignals can be processed and decoded to achieve reasonable throughput ofcolor text data to a Remote PC. Future embodiments could add circuitryand/or software to allow simultaneous processing of all color signalsby, for example, pre-digitizing each color signal (using shift registersand latches, as described in FIG. 4K) and storing this data into aseparate memory storage area before passing this information to theVideo Processor 111 circuitry. This alternative approach would permittext and graphics color attributes to be more precise by avoidingpotential discrepancies caused by processing multiple scan cycles whereVDAC screen data changes between each cycle.

As shown in FIG. 4H, analog color signals vary from zero volts 272 forblack 278 to approximately 0.7 volts 270 (into a 75 ohm load) for white275. Light gray 276 and dark gray 277 are between these two limits. Tobe processed by the present video circuitry, this analog signal needs tobe converted to a digital TTL signal. To accomplish this, a thresholdlevel is set 271 so that color levels above this level 274, 275, 276 areconverted to a LOGICAL 1 (high) signal 281. Color levels below thethreshold such as 273, 277, 278, etc. will be converted to a LOGICAL 0(low). The resulting VGA Video output signal 280 is depicted beginningat reference point 280 and is the output of the circuit as shown atreference point 297. Using this present approach, a foreground color ofdark gray 277 on a background color of black 278 will not be discernedby the circuitry. Neither will a combinations of white 275 and lightgray 276. Also, although white, gray, and black 275, 276, 277, 278 arereferenced, the actual color depends on the color signal selected andwill be either red, green, or blue. The analog color signals 290, 291,292 are selected by an Analog Signal Select multiplexer 293 andpresented to the positive input 294 of a comparator 296. The minus input295 is fixed at a threshold value 271. The output of the circuit 297 isa TTL signal as illustrated beginning at reference point 280. Thecircuit could use, for example, an Analog Devices part AD9696comparator.

The Video Processor handles both digitizing graphics and text modecharacter recognition. For processing purpose a “pixel” is equivalent toa “logical bit”.

As shown in FIG. 41 block 300 depicts a VDM displaying six characters:“A”, “B”, “C”, “D” and two characters from the extended ASCII characterset, namely a solid block and a cross. As shown on FIG. 4J, the totalvideo signal is composed of several parts: Vertical sync 340, horizontalsync 343, and color signal(s) 350 (illustrated as only one signal).Whereas color VDAC uses red, green, and blue signals, monochrome VDACoften use green and intensity signals only. As shown in FIG. 41, thevisible portion of the VDM 302, where text and graphics appear, is onlya subset of the total video signal. Block 310 shows a close-up view ofthe upper, top left corner of the entire VDM 301 which includes part ofthe left, top corner of the visible VDM 302.

As shown in FIG. 4J, the vertical sync signal 340 commands the monitorto go to the top of the screen 301, 313 and start scanning downward tothe bottom of the screen. 304. The horizontal sync signal 343 commandsthe monitor to go to the left side of the screen 305, 325 and scan tothe right side of the screen 303. The color signals create visible lighton the VDM's screen in the form of text and/or graphics 302. Although314 depicts the first visible horizontal scan line, there are horizontalscan lines above (see 301, 313, and 352) the first visible scan line314. As shown in FIG. 4J, reference 345 illustrates the first visiblehorizontal scan line and reference 348 illustrates the last visiblehorizontal scan line. References 330 and 333 expands a single horizontalscan line 346. Although the first scan line 314 and the last scan line315 for a character row represents 16 horizontal scan lines (typical forVGA text mode), some older monochrome VDAC only generate 8 horizontalscan lines as shown at reference 353 between references 345 and 346.Reference 334 shows the first character row's horizontal scan line 316over the “C” character on FIG. 4I. Similarly, reference 336 representsscan line 316 over the “D”. Reference 338 is the same scan line over the80th character (not shown on FIG. 4I). Reference 347 represents the nexthorizontal scan line at 317. The horizontal sync pulse 330 starts thehorizontal scan line 316. There is a delay 335, 325, 305 before thefirst visible horizontal pixel 324.

References 324, 322, 321, and 320 position the first pixel of eachcharacter of a given row. The 9th position 323 which is preset for VGA,Hercules, and other VDAC (not for early monochrome VDAC which is 8 by 8)is not taken into account. The pixel clock signal only captures thefirst 8 pixels of the character so that the digitized video ignores thispixel 323.

The first horizontal scan line (non-visible) 344 is depicted atreference 312 on FIG. 4I. The last visible scan line 348 completes aVDM's screen. Presently, VGA text mode has 350 visible horizontal scanlines, VGA graphics mode (640×480) has 480 scan lines, hi-res mode (800by 600) has 600 scan lines, but the present system is capable ofoperating with any number of differing graphics modes and display lines.

After the horizontal sync pulse 330, and the left margin delay 305, 325,335, the visible video occurs as illustrated at reference 337. A scanline for the first two characters is shown in FIG. 4K beginning atreference 360. The preferred embodiment of the Video Processor uses a 16bit shift register and a 16 bit latch. FIG. 4K, however, only depicts an8 bit latch and shift register for illustration purposes.

As an example of the process of digitizing video characters, assume eachcharacter is 8 pixels wide, as illustrated beginning at reference 365and ending at reference 370. When digitized, these eight pixel valuesmake up the eight bits of a byte used for further processing. After the8th pixel 370, there is a 9th unused pixel labeled “X” (shown atreference 375). This 9th pixel occurs for VGA VDAC as well as somemonochrome VDAC. Some VDAC do not have this pixel so that the last pixelof one character 370 is immediately followed by the first pixel of thenext character 373.

Reference 361 shows an actual wave form from a horizontal scan lineillustrated on the graph 390, as the last horizontal row at the base ofthe characters “L” and “M” ending with the pixel referenced at 394.Reference 364 shows the bottom line of the “L”, reference 371 shows theleft leg of the “M”, and reference 374 shows the right leg of the “M”.

The video pixel data 365 input 391 to the shift register 393 will appearat the first shift register output bit 395 after a clock pulse at 392.After 7 more clock pulses, the video pixel data 365 appears at the lastshift register output bit 399. Thus, to digitize a character, each pixeldata bit (e.g. 365) is shifted into a shift register 393 from Videosignal input 391 via a Pixel Clock 362, 392. After the 8th pixel 370 isshifted into the shift register, the data is transferred into the Latch398 via the Latch Clock 363, 372 at 396. After the data is latched, theoutput of the Latch 398 indicated at reference 397 is then stored intothe Video Output Buffer 115 (FIG. 4A) for later retrieval by the VideoCPU 114 (see FIG. 4A). For VDACs where the last pixel of one character370 is followed immediately by the first pixel of the next character373, then Latch Clock 372 occurs coincident with the first pixel of thenext character.

Once in the Video Output Buffer 115 (FIG. 4A), the digitized video datacan be transferred, through the Control CPU 106 (FIG. 4A) and out theRemote Data Circuitry 103 (FIG. 4A) to a Remote PC 2 (FIG. 1), which canthen be directly displayed in graphics mode. Although presentlysupported, this transfer requires sixteen bytes per character whichslows down the transfer of screen data to a Remote PC. In cases where aHost PC VDAC is in a text mode, screen transmission times can be cutdramatically by converting a character's 16 byte packet into a one bytecharacter code, such as used by the ASCII coding scheme, andtransmitting only the one byte code instead. Depending on the particularVDAC, characters can use 8, 9, 14, or 16 horizontal scan lines or bytepackets, all of which are handled by the Host Unit's circuitry. Forillustration purposes, 16 horizontal scan lines (presently used by VGAVDAC) has been selected for further discussion.

The conversion from pixel data to characters requires some kind ofcharacter recognition of which several approaches are possible. Thefirst approach is to take the digitized video and search a look-up tablefor a match of this character's 16 byte packet, which represents there-organized pixel data which corresponds to a single character. Therelative position in this table would then yield the character code,such as used by the ASCII coding scheme, associated with the desiredcharacter. This method is less preferred because the particular shapesof characters vary among different VDACs and the look up table wouldrequire excessive storage of character set mappings. Furthermore, thetable would have to be updated to handle new character sets or characterformat changes.

A second approach would be to process the digitized video data bycertain algorithms which directly infer (or recognize) the character'sidentity such as those typically used by OCR (optical characterrecognition) software familiar to persons in the trade. This approach isless preferred because it is computation intensive requiring too muchprocessing on the part of the Video CPU 114 (FIG. 4A), which slows videoscreen access by a Remote PC and degrades throughput to a Remote PC.

A third approach, which is employed in the most preferred embodiment ofthe invention, uses CRC methods for character recognition. Under thisapproach, the digitized video is converted directly to CRC values byhardware circuitry, after which these values are written to the videooutput buffer.

To convert a 16 byte packet to a unique CRC value, the packet data isserialized (dropping the ninth pixel, if present) and the resulting bitstream is input to the CRC generator. FIG. 4L illustrates this process.Each horizontal scan line for a particular character 410, 411, and soforth down to 417, is processed sequentially as shown beginning atreference 400. It can be seen that the tip of the “A” (see 412) isfollowed immediately by the top line of the “B” as shown within block407. In the most preferred embodiment, the CRC generator is morecorrectly called a CRC processor, in that intermediate CRC valuesgenerated can be saved and then later restored to process the nexthorizontal scan line. First the CRC shift register value is set to zero.Then the first line of the cell containing the “A” 410, 401 isprocessed, after which the intermediate CRC value is saved. Then the CRCshift register value is again cleared and the first line of the cellcontaining the “B” (see 407) is processed, and so on. After the entirehorizontal scan line 410 is processed, scan line 411 begins. First, thepreviously saved intermediate CRC value for the cell containing the “A”is loaded into the CRC shift register. Then, 402 is processed afterwhich again the intermediate CRC value is saved, and so on. Thus, whenprocessing 80 column text data, there will be 80 intermediate CRC valuessaved for each scan line. This allows the CRC generator to “see” 16contiguous bytes for each character. After the last horizontal line 417for the “A” is processed, the resulting CRC value is the CRC for thecharacter and is stored into the Video Output Buffer 15 (FIG. 4A) and soon for the remaining characters. Later the Video CPU 114 (FIG. 4A) readsthese CRC values and searches a look-up table of character CRC valuesfor a match. A special initial training process, discussed in moredetail below, generates this table of CRC values, which reflect theactual VDAC characteristics of the Host PC. This process translates theactual character formats used by a given VDAC to a unique CRC for eachdifferent character.

Another approach to convert pixel information to character format wouldbe to store all 16 horizontal lines of digitized data (16 by 80 bytes)and then process each character in serial order 400. Two banks of 16 by80 byte memory would be required so that new digitized data could bestored while previously stored data is being converted to CRC values.This approach uses software instead of hardware to do the processing,but otherwise is suitable for use in the present invention.

The Host Unit's circuits could be enhanced to include a memorytranslation circuit between the Video Processor 111 (FIG. 4A) and theVideo Output Buffer 115 (FIG. 4A) where the CRC value output from 111(FIG. 4A) would form the address which accessed a memory byte containingthe character code, such as used by the ASCII coding scheme, for thecharacter and store this code into the Video Output Buffer 115 (FIG.4A). The Video CPU 114 (FIG. 4A) would then read the character codesfrom the video output buffer.

FIG. 4M gives an overview of the current implementation of the VideoProcessor 111 (FIG. 4A). The CRC generator is composed of a 16 Bit ShiftRegister 439 (rather than 8 bits as shown in FIG. 4D) and a 9 bit ParityGenerator 423 (rather than EXCLUSIVE OR gates as shown in FIG. 4D). Theoutput of the Parity Generator 421 is input to the Shift Register 439.The particular output bits of the Shift Register 439 which are summedwith the Video Input 420 is controlled by a Feedback Select circuit 425(8 dual input AND gates). The first 7 least significant bits along withthe most significant bit of the shift register output 426 is logicallyANDed with 8 “enable” bits 428 from a CRC Config Latch 429. This latchis set by the Video CPU 114 (FIG. 4A) and configures which of these 8shift register output bits 426 are input to the parity generator. ThisLatch 429 is used to configure the CRC generator to produce unique CRCvalues for the video character set to be recognized. If this value 428is set to zero, then all 8 bits in 424 will also be zero and the parityoutput 421 will directly reflect the Video Input signal 420. It is bythis means that the Video Input 420 is digitized, with the latched data442 being stored directly into the Video Buffer 444, without beingchanged by the CRC generator.

The Pixel Clock 422 clocks video pixel data into the CRC shift register439. As shown in block 454, the first pixel of the second character 453directly follows the last pixel of the first character 452. The 9thunused bit (referred to earlier) does not appear on the graph on FIG. 4Mas it does not have an associated pixel clock.

The Temporary CRC buffer 438 is cleared by Clear line 433 being pulsedby the vertical sync signal. The Shift Register 439 is cleared to zerovia 431. Then, 8 Pixel Clocks 422 occur coinciding with the 8 pixelsstarting with 451. After the 8th pixel 452 is processed, theintermediate CRC value now appearing at the Latch input 427 is latchedvia the Latch clock 440. The shift register 439 is again cleared via 431and the next character is processed starting with pixel 453. While thisnext character is being processed, the value previously latched 441, 442is written to a temporary CRC buffer 438 by pulsing the write line 443.This continues until all characters are processed for this horizontalscan line and the Temporary CRC Buffer 438 contains 80 intermediate CRCvalues. Then, the next horizontal scan line begins. Before pixel 450 isprocessed, the previously saved intermediate CRC value in the TemporaryCRC Buffer 438 is loaded into the Shift Register 439 via the read line437, 432, mid 430. After the 8th pixel is processed, the newintermediate CRC value is again latched 441 and stored into theTemporary CRC Buffer 438, as described above.

This process continues until a horizontal scan line 455 begins. For thisscan, intermediate CRC values are restored as before, but after pixel456 occurs, the latched CRC value at 442 is the final CRC valueidentifying the character processed (“A” in the example) and is storedinto the video buffer 444 via the write line 445. This is true for theremaining characters on this scan line 455. The next scan line beginsthe next row of characters and the process starting at 451 repeats untilall 25 (for an 80 by 25 video text mode) rows of characters areconverted and all 2000 character CRC values are stored into the Video(output) Buffer 444, which is the same as the Video Output Buffer 115 inFIG. 4A.

A possible alternative to storing CRC values in the Video Buffer 444would be to convert the CRC values before storage into the Video Buffer444. This could be accomplished by inserting a memory circuit before thevideo buffer, which would function as a look up table whereby the 16 bitCRC value referenced at 442 will form the memory address. The resulting16 bit output of this memory would contain the character relating to agiven CRC. The Video CPU would initialize this memory with CRCinformation. For invalid CRCs the 16 bit value is set to zeros. Fornormal character CRCs the low byte is set to the ASCII code of thecharacter and the high byte would be set to zero. For highlighted(inverse) character CRCs the high byte would be set to the ASCII codeand the low byte would be set to zero. This approach would permitimmediate translation of CRCs to characters and would improve Host Unitperformance.

As shown in FIG. 4N, the video pixel duration as generated bymonographic VDACs is about 65 nanoseconds, and for VGA VDACs it is about30 nanoseconds. The Video time line 458 shows three video pixels: awhite, a black, and another white pixel. VGA video requires a fast PixelClock 459. The slanted lines indicated by 461 shows jitter produced whenany two asynchronous signals interact (the video signal and the HostUnit's video clock). Using 90 megahertz as the base clock rate for pixelclock generation (in the current implementation) this jitter is about 11nanoseconds in duration. Thus, because of this jitter, to position therising edge of the pixel clock near the end of the video pixel as shownat reference 460, a resolution of 5 nanoseconds was incorporated intothe design. Thus, if reference 467 shows the pixel clock at 460, thecircuitry can reposition the pixel clock at 468, or 5 nanoseconds later,if needed. This would make the base clock appear to be between 180 to200 megahertz. Of course, since the base dock in the currentimplementation is 90 megahertz, or a period of 11 nanoseconds, and thedelay is 5 nanoseconds, the position of the pixel clock follows thepattern 0 ns, 5 nanoseconds, 11 ns, 16 ns, 22 ns, etc. That is, it iscentered around a 190 megahertz resolution, and it is a practicalsolution to achieve the desired result (i.e. to clock in a stable pixeldata bit).

To explain jitter, the rising edge of the Horizontal Sync 462 pulsesynchronizes the pixel clock. Jitter is inherent in that it cannot beknown in advance what the phase of the base clock will be at this time.In fact, the phase of this clock will be continuously changing inrespect to each new horizontal scan. To illustrate this, 463 and 464show the base clock in different phases. Note that the rising edges ofthe base clock 465 and 466 occurs at different times after the risingedge of the sync pulse 462. Since the Pixel Clock 460 is derived fromthis sync signal and the base clock, the video pixels 458 inherit thejitter as shown at 461. The start and end of each pixel will fluctuatewithin the area shown at reference 461.

The current implementation of the Pixel Timing Circuit 112 (FIG. 4A) isshown in FIG. 40. Presently, this circuit is a 4K by 8 bit 20 nanosecondRAM memory. The Video CPU 114 (FIG. 4A) programs this memory via thedata in 470, and the write line 477. This memory is addressed by theoutput 483 of a 12 bit counter 484. First, this counter 484 is clearedvia reference 485 and, after each write pulse, increments the addresscounter via reference 486 (this connection is not shown on the figure).When processing video, the read line 478 is enabled. The horizontal syncsignal clears the address counter via the clear line 485. The outputbyte of the RAM memory 471 is split into two 4 bit nibbles 472 and 479and are loaded into two 4 Bit Shift Registers 473A and 480. A 90megahertz Oscillator 489 clocks these shift registers and, via the clocksignal 488 and the Divide By 4 circuit 487, loads the two nibbles intothe shift registers every fourth clock cycle and then increments the 12Bit address Counter 484. The two shift registers then output each 4 bitnibble one bit at a time at references 473B and 481 to generate thePixel Clock signal 476. The output of the Shift Register 481 is delayed5 nanoseconds via a 5 ns Delay 482 (presently a DALLAS DS1000-25) andthe two signals 473B and 474 are logically ORed via reference 475 toproduce the Pixel Clock 476. Thus, the pixel clock generated can bealigned to the 90 megahertz clock rate every 11 nanoseconds or delayed 5nanoseconds. Only one bit of one nibble at a time can become the pixelclock. Other means which could be employed include using a phase lockloop (PLL) or other precision delay elements to generate the pixelclock.

The polarity of the vertical and horizontal sync signals change, as wellas their relationship to each other, depending on the VDAC in use andthe particular video mode (e.g. text or graphics modes). As shown inFIG. 4P., references 490 and 491 show example Vertical Synchronization(Sync) 490 and Horizontal Synchronization (Sync) 491 signals. But,depending on the video mode or VDAC, the Horizontal Sync 491 may appearas shown at reference 492 and the Vertical Sync signal 490 may appear asshown at reference 501. To accommodate this, two exclusive OR gatesreferenced as 498 and 500 are used so that the sync signals which drivethe video circuitry are always negative polarity at references 497 and499. The Video CPU 114 (FIG. 4A) sets the polarity bits referenced at494 and 496 to accomplish negative polarity.

The phase relationship of the vertical and horizontal sync signals alsovary per VDAC as shown at references 501 and 503. Both rising edgesoccur at the same time. Referring to references 503 and 504, notice thatthe rising edge of 504 occurs after the rising edge of 503 as comparedwith the phase relationships shown at references 501 and 502. Tonormalize this to a consistent phase relationship, a flip-flop is usedas shown at block 508. The VSYNC Temp signal 499 is used to clear theflip-flop as shown at reference 510 and the rising edge of the HSYNC Outsignal 497 which is connected to the clock input 507 and sets the output509 to a one (logical high) via data input 506 (hard-wired to +5 volts).The VSYNC Out signal is shown as reference 505.

The Horizontal Control Circuitry 113 (FIG. 4A) implements the narrativeand timing diagram for FIG. 4J and FIG. 4M. Referring to FIG. 4J, afterthe vertical sync begins a new screen at references 340 and 351, thiscircuitry skips the non-visible horizontal sync signals referenced at352, then repeats the cycle of initializing the CRC shift register 439value to zero 431, for each character of the first horizontal scan line,saving and restoring intermediate CRC values via 438 for the middlecharacter scan lines, and writing the final CRC values for eachcharacter row to the Video output Buffer 444 (115 FIG. 4A).

The Host Unit contains two microprocessors (i.e. CPUs) 106, 114 eachwith their own independent software operating system. FIGS. 5A through5I provide an overview of these software operating systems. Sourceprogram code written in 8032 assembly language for the Video CPU 114 iscontained in the microfiche appendix, part 5. Source program code alsowritten in 8032 assembly language for the Control CPU 106 is containedin the microfiche appendix, part 6. As known to persons familiar to thetrade, operating system software, such as that used for the Control andVideo CPUs, is primarily event or interrupt driven and does not followthe linear logic flow typical of most application software.

The present embodiment includes two CPUs primarily to spread theprocessing workload so as to give a remote user the impression (to theextent possible) that they are actually sitting at the Host Unit.Decoding the high speed video signal of the Host Unit's VDAC presentlyrequires almost all of the processing speed of a typical high speedmicroprocessor. Adding additional processing requirements to the CPUresponsible for decoding video signals may prevent the CPU from keepingup with the data output of a VDAC. Hence, a second CPU was added to thepresent design of the Host Unit. As noted above, however, with fastermicroprocessor technology, a single CPU could be used.

FIG. 5A represents an overview of the Control CPU 106 (FIG. 4A)operating software. When power is first applied to the Host Unit, theCPU begins executing the initialization routine 600. This routine doesthe nominal housekeeping such as setting certain variables to defaultvalues, clearing counters, setting up interrupt parameters. After this,the dip switches are accessed to determine the Host Unit'sidentification number. Then, non-volatile ram is accessed 108 (FIG. 4A)for the Host Unit's access password, default modem data and to check ifthe Host Unit is setup to process video (via training discussed below inconnection with FIG. 6).

If the Host Unit is ready to process video data, a video-ready commandis sent to the Video CPU (via 107 FIG. 4A) to indicate that videoprocessing can commence. The initialize routine 600 then sets up theRemote Data Circuitry's serial data port 103 (FIG. 4A). If the HostUnit's identification number is zero, the Host Unit's data port isdisconnected from the chaining port, the CPU's serial port transmit andreceive signals are directly connected to the host data port, and amodem which is expected to be connected to the remote data port, isinitialized. In a case where a Remote PC is directly connected to a HostSite via a Direct Line Linkage, no Host Unit with an identificationnumber of zero would exist at the Host Site. In this instance, theRemote PC would presently be connected directly to the “Data In”receptacle of the first Host Unit on the Daisy chain. In this case, thefirst and all other Host Units present on the daisy-chain listen for anaccess request.

After this initialization process is complete, the Control CPU waits toProcess Access Requests 601 from the Remote PC to the Host Unit. Duringthis time, the “Action” button on the front of the Host Unit is alsomonitored. Should the “Action” button be pressed, then normally a“Setup” command is sent to the Video CPU and a “Setup” flag is set, thesetup indicator on the front panel of the Host Unit is made to blink,and the Process Access Request 601 routine continues to wait. However,in cases where the Host Unit has been locked due to a security breach,pressing the “Action” button unlocks the Host Unit for remote access andresets both the “Session” and “Lockout” counters to zero. Finally,during this Process Access Request 601 wait period, any command receivedfrom the Video CPU will be serviced. Then, the Process Access Request601 routine continues to wait.

When a Remote PC first establishes a connection with a Host Site (i.e. acarrier detect signal or a request to send received), each Host Unit onthe daisy-chain at the Host Site re-initializes it's “Session” securitycounter to zero and session lockout flag.

When a Remote PC issues an access request, each Host Unit at the HostSite checks it's identification number 601. If the Access Request'sidentification number matches the Host Unit's number, then the Host Unitresponds to the access request and Password processing 602 begins.However, if the unit is currently in a SETUP mode, the Process AccessRequest 601 responds BUSY and access is denied.

Routine 602 now requests a password from the Remote PC and waits.Presently, the Host Unit uses a zero knowledge password protocol,whereby each password request contains a random encryption key thatencodes the password in a different manner, so as to make it difficultfor anyone with unauthorized access to the data line to determine apassword.

If no password is received after a pre-set period of time or an invalidpassword is received 603, then a “Session” counter is incremented tocount the number of unsuccessful access attempts during a session. Ifthis counter exceeds a user specified limit, the counter is reset tozero, a “Lockout” counter is incremented, a session lockout flag is set,and a data packet is returned to the Remote PC indicating that access tothe Host Unit is denied for the session and processing returns to theProcess Access Request routine 601. If the “Lockout” counter exceeds auser specified limit, as obtained from non-volatile RAM, no user will bepermitted access to the Host Unit until the “Action” button on the frontof the Host Unit is pressed.

If a valid password is received 603, both the “Session” and “Lockout”counters are reset to zero, the session lockout flag is cleared and theProcess Command routine is invoked 604.

The Process Command 604 routine, processes any commands received fromthe Remote PC or the Video CPU. The Misc. Commands subroutine 608contains some subroutines that may be invoked by the Video CPUprocessing, after which processing will return to the calling routinewhen complete.

The Release-Access command 605 is not a subroutine, but causes an end tocommand processing by returning to the Control CPU's Process AccessRequest routine 601.

The Passthru 606 and Remote Access 607 routines are described after ageneral discussion of the Video CPU has been completed below.

Several processes are grouped together under the heading Misc. Commands608. These processes include disconnecting the Host PC's keyboard fromthe Host PC so that the Control CPU can generate the keyboard signal.Also included are commands which start a video training sessionremotely, or transfer video related data (contained in non-volatile ram)to and from the Remote PC, change the Host Unit's password, or send akeyboard scan code to the Host PC (used by the video CPU duringtraining).

FIG. 5B is an overview of Video CPU's operating software. Lines witharrows indicate processing flow, whereas lines without arrows indicate acalled process or subroutine.

When power is first applied to the Host Unit, the Video CPU beginsexecuting the initialization routine 620. This routine does nominalhousekeeping such as setting certain variables to default values,setting up interrupt parameters, and initializing the Host Unit's dataserial port 116 (FIG. 4A). After this, the software waits for a command621 from the Control CPU 107 (FIG. 4A). Blocks 622, 623A, 624, 625 andthe miscellaneous command 626 are all subroutines invoked by the WaitFor Command 621 routine, which returns processing to the Wait ForCommand routine 621 when subroutine processing is complete. Blocks 623Athrough 623E are parts of a single subroutine.

If the Control CPU sends a video ready command, then the Load VideoRelated Data 623A subroutine is invoked and waits for one second, andthen requests non-volatile video related data from the Control CPUnecessary to decode the Host PC's video output. After this data isloaded into the Video CPU's memory 623A, the video processor hardware110, 112, 113 (FIG. 4A) is initialized 623B with timing data, defaultsync polarity, and also flags are set to indicate the video processingmode (monochrome or color). Then, the Accumulate History 623E processbegins to perpetually log the most recent VDAC output history to theextent of the Host Unit's memory.

If the video mode changed from a text mode to a graphics mode, historylogging within the Host Unit is suspended until the video mode returnsto a text mode.

The Accumulate History process 623E initially captures the text datacurrently displayed by the Host PC's VDAC which is stored in a “basescreen” data area and after this, the Accumulate History Process onlyaccumulates any changes which occur. If so many changes occur that theVideo CPU's memory limit is reached, then the oldest changes are appliedto the “base screen” data area to free up more memory so that morerecent changes can be stored.

When a Host Unit is initially accessed by a remote user, the remote usermust specify (via the TVLINK.EXE program operating on the Remote PC, asdiscussed below) whether or not (1) any screen history stored in theHost Unit's memory should be transferred to the Remote PC prior tobeginning the access session and (2) if the user wants view only accessto the Host site, as opposed to full access. The user's preference onvideo history and view only mode is transferred to the Host unit as datapackets when the Host Unit is first accessed. If video screen history isto be transmitted, then the Accumulate History routine 623E transmitsVDAC history data to the Remote PC by the Video CPU through the ControlCPU's Misc. Command Routine 608 in the form of data packets andprocessing returns to the Wait For Command 621 routine. Otherwise, theprocessing returns to the Wait For Command 621 routine.

If the remote user has requested full access to a Host Site's HostUnits, as opposed to view only access, the Remote PC sends a RemoteKeyboard command to the Host Unit which invokes the Misc. Commandssubroutine 608 that causes the Host PC's keyboard signals to begenerated by the Host Unit instead of the Host PC's keyboard. Then, theRemote PC sends a Remote Access command to invoke the Remote Access 607subroutine.

First, the Control CPU Remote Access 607 subroutine instructs the VideoCPU to begin it's Remote Access 622 subroutine processing. The RemoteAccess subroutine 622 causes video text to be captured and sent via theControl CPU to the Remote PC for display. The last status of the screendata sent is compared to the contents of the current screen and onlychanges in the VDM data are sent.

FIG. 5C shows an overview of the data flows between the TVLINK.EXEsoftware executing on the Remote PC 630A, the Host Unit 630B, and theHost PC 630C. Remote keyboard 631A and mouse 631B activity are handledby TVLINK.EXE interrupt processes which combine and transmits this data633, 634 to the Host Unit 632. The Control CPU 636A separates this data,sending mouse information to the Video CPU 636B which forwards it asserial input 638 to the Host PC. The keyboard data transmitted isconverted to keyboard clock and data signals 637 which pass into theHost PC's keyboard input receptacle. Host PC Video signals 639 from theVDAC are converted to coded text data, such as ASCII coded text data, bythe Video CPU and transmitted through the Control CPU to the Remote PC635 where it is processed by TVLINK.EXE for output to the Remote PC'sVDAC. Note that the transmit and receive data lines shown at 632 may beconnected directly or connected via modems or other communicationdevices.

To accomplish file transfers between the Remote PC and the Host PC,first a file-transfer program called TVFILES.EXE (provided with theapparatus and installed on the Host PC's mass storage device) is invokedon the Host PC by typing in the program name from the Remote PC keyboardusing the Remote Access process 607. Then the file transfer function isselected from the TVLINK.EXE menu of the Remote PC. TVLINK.EXE will thensend a packet containing a Passthru command to the Host Unit. TheControl CPU receives this command 604 and Passthru mode 606 subroutineis invoked.

The Passthru Mode 606 subroutine first sends a Passthru command to theVideo CPU's Wait For Command 621 routine which causes the Passthru 624subroutine in the Video CPU to be invoked. The Control and VideoPassthru 606, 624 subroutines work together so that data received fromthe Remote PC is forwarded via the Video CPU to the Host PC's serialport. Data received from the Host PC is forwarded via the Control CPU tothe Remote PC. Thus, TVLINK.EXE (running on the Remote PC) communicatesdirectly with the file-transfer program (running on the Host PC) and itis the responsibility of these two programs to produce the file transfereither from the Host PC to the Remote PC or vice-versa.

Video Training and Setup 625 is invoked when the Setup command isreceived from the Control CPU, after the Action button is pressed on thefront panel of the Host Unit. This process interfaces with a softwareprogram running on the Host PC called TVTRAIN.EXE, which is providedwith the apparatus and accessible from the Host Unit's mass storagedevice, as discussed in the narrative supporting FIGS. 6A to 6D. To senddata to the program, the Video Training and Setup subroutine 625commands the Control CPU to send “keystrokes” to the program, andreceives data from the program by processing the VDAC's video signalsincluding a video raster signal. This process is described in moredetail in connection with FIGS. 6A, 6B, and 6C.

During Remote Access 622 and Video Training and Setup 625, certainsubroutines are used to capture and interpret video data. Video graphicsis captured and digitized by the Capture Video 640 graphics subroutine.This subroutine first checks that the horizontal sync and the verticalsync did not change in polarity, and then waits for the vertical sync tobecome active, at which time it enables the video processing circuitryand waits for the next vertical sync. At this point, the video outputbuffer contains the digitized video data. This data is then transmittedto the Remote PC where TVLINK.EXE program can display this data ingraphics mode. This data is also used by the training process (describedbelow) to adjust pixel clock timing. The video circuitry must beproperly initialized (see 110, 111, 112, 113 FIG. 4A) without CRC.

If the polarity of the sync signals change 641, this routine aborts andreturns 642 the Video Status. Otherwise the Capture Video 640 graphicssubroutine returns OK 643.

To capture video text, the video circuitry must be properly initialized(see 110, 111, 112, 113 FIG. 4A) for text mode with CRC. Then, theCapture Video 644 text subroutine captures video text and 2000 CRC's(for a 80 character by 25 line text mode). Presently, both the Graphicsand Text Capture Video subroutines 640, 644 are the same subroutine.This results because the video processing circuitry is initializeddifferently that character CRC's, rather than digitized video, is storedinto the video output buffer.

If the sync polarities have changed 645, Capture Video 644 subroutineprocessing ends and the video status is returned to the calling routine646. Otherwise, the video circuitry loads each character CRC from thevideo output buffer and, via a look-up table, translates these CRCs tocharacter codes (such as one byte character codes used by the ASCIIcoding scheme) stores these codes into memory via a data-pointer whichwas initialized prior to calling this subroutine 647, and then returnsOK 648.

FIG. 5E shows the Capture Video 644 subroutine (at 650B, 651B, 652B)being used to capture text data from the red, green, then blue colorsignals. Before capturing text data, the particular color signal isselected at 650A, 651A, 652A (discussed previously in the narrative forFIG. 4G). The Capture Video Text 650B, 651B, 652B subroutine will returnthe video status 650D, 651D, 652D if the sync polarities change 650C,651C, 652C. Otherwise, the Capture Video Text subroutine returns OK at653 after capturing video text information from the Red, Green and Bluecolor signals.

FIG. 5F illustrates some of the data storage areas used by videosubroutines. The character data generated from the Capture Video Textsubroutine 650B, 651B, 652B is stored into corresponding data areas660A, 661A, 662A. These subroutines also update a bit flag (in 660B,661B, 662B) for each character. A bit flag indicates whether a characteris normal or inverse (highlighted).

Using the red, green, and blue text data and bit flags, each charactervalue, such as the ASCII value, and color attributes (foreground andbackground) can be determined. FIG. 5G shows 5 characters 665A, 665B,665C, 665D, 665E, each with different foreground and background colorcombinations. For each of these, there is also shown the charactersderived from the three color signals after each signal is used to derivethe related CRC. The foreground and background colors will be eachrepresented by a three bit number with each bit corresponding to one ofthe three primary colors. This three bit quantity can take on values0-7, where black is 0 (000b), blue is 1 (001b), green is 2 (010b), lightblue is 3 (011), red is 4 (100b), violet is 5 (101b), yellow is 6 (110b)and white is 7 (111b). The preceding numbers in parenthesis are thebinary equivalent of the three bit value and will be used in thediscussion. The combination of red, green, and blue light make white. Incases where the analysis of a color signal yields a CRC that is “normal”video, the corresponding bit value of that signal will be 1 for ON and 0for OFF. Otherwise, if the signal matches an inverse CRC, the bit valueof the signal will be reversed (i.e. set to 0 for ON and 1 for OFF).

The process of how the three-color primary color signals are used toderive the foreground and background colors is illustrated in FIG. 5Gand FIG. 5H.

For White (foreground) on Black (background) 665A, each color signalmatches a “normal” CRC for an “A”. Accordingly, 666A shows a red “A” ona black background, which means the red signal is ON for foreground(i.e. 1) and OFF for background (i.e. 0). Similarly, 667A shows a green“A” and 668A shows a blue “A”, also on black backgrounds. Together thesethree color signals appear on a computer monitor as a white “A” on ablack background. On this basis the bit values would yield: Foreground:111b, background: 000b.

For White on Blue 665B, the blue signal 668B is always on. It suppliesthe blue background color and it also combines with the red “B” 666B andthe green “B” 667B to create the white foreground color of the “B”. TheCRC for the red and green signals yield a “normal” B character. Hence,the first two foreground bits are “11” and background bits are “00”. TheCRC for the blue signal yields a “normal” solid blue block CRC characterwhere both the foreground and background colors are blue (i.e. ON).Hence, both the third foreground and background bits would be set to 1.On this basis the bit values would yield: Foreground: 111b, background:001b.

For Yellow on Blue 665C, the red “C” 666C and the green “C” 667C are ONand combine to create the yellow foreground color. When the red andgreen signals' CRCs are analyzed, a “normal” CRC “C” character results,which means the first two bits are set to foreground value of 1 and abackground value of 0. When the blue signal's CRC is analyzed, the bluesignal 668C forms the background only and is not part of the foregroundcolor, since the signal matches a “inverse” CRC for the letter “C”. Onthis basis the bit values would yield: Foreground: 110b, background:001b.

For Red on Blue 665D, the red “D” 666D creates the foreground color andhence matches a “normal” CRC for the letter “D”. So, the first bit wouldbe set to 1 for the foreground and 0 for the background. The greensignal 66713 is off, or black; does not contribute at all; and matchesthe CRC value for a “normal” space. So the second bits for both theforeground and background would be set to 0 (i.e. OFF). When the bluesignal's CRC is analyzed, the blue signal 668D forms the background onlyand is not part of the foreground color, since the signal matches a“inverse” CRC for the letter “D”. On this basis the bit values wouldyield: Foreground: 100b, background: 001b.

For Yellow on Violet 665E, the red signal 666E is always on and with thegreen “E” 667E combine to create the yellow foreground color andcombines with the blue background color 668E to form violet. Since thered signal is “ON” to achieve both the foreground and background colors,the red signal matches the “normal” CRC for a block character and thefirst bit for both the foreground and background would be set to 1. Thegreen signal combine with the red signal to define the yellow foregroundfor the “E” character, but is not a part of the background color and ishence OFF for background purposes. On this basis, the green signal wouldmatch the CRC for a normal “E” character and cause the second bit to beset to 1 for the foreground and 0 for the background. The blue signal668E does not contribute to the foreground but contributes to thebackground and combines with the red signal 666E to form violet. Whenthe blue signal's CRC is analyzed, the blue signal 668E forms thebackground only and is not part of the foreground color, since thesignal matches a “inverse” CRC for the letter “E”. On this basis the bitvalues would yield: Foreground: 110b, background: 101b.

For Yellow on Green 665F, the blue signal 668F is off, or black, anddoes not contribute anything. Hence, the blue signal translates to a CRCfor a “normal” space, where the third bit would be off for both theforeground and background. The green signal 667F supplies all of thebackground color and also combines with the red signal 666F to createthe yellow foreground color. Hence, the CRC for the green signal yieldsa “normal” block character where both the foreground and background forthe second bit would be set to “1”. The red signal only contributes tocreating the foreground of the “F”. Hence, the red signal would yieldthe “normal” “F” character which would set the first bit to a foregroundof “1” and a background of “0”. On this basis the bit values wouldyield: Foreground: 110b, background: 010b.

For Black (foreground) on White (background) 665G, each color signal isidentical and yields the CRC for an “inverse” “G” character. 666G showsa black “G” on a red background. Similarly 667G shows a black “G” on agreen background and 668G shows a black “G” on blue background. Togetherthese three color signals appear on a computer monitor as a Black “G” ona white background. On this basis the bit values would yield:foreground: 000b, background: 111b.

Other characters follow a similar pattern, except for those characterswhich result in a solid block or a space.

When an analysis of all three color signals yields a character that is asolid block 665X, 665Y, 665Z, the character ASCII code is always storedas a hex DB block with both the foreground and background attributes setto the color of the block. This approach improves processing efficiencyas discussed below.

A Black block is shown at 665X. All the color signals 666X, 667X, 668X,are off, or black. The CRC for each color character 666X, 667X, 668Xwill be translated to a “normal” space character (ASCII hex 20) but thecharacter at 665X will be set to a block (ASCII hex DB) with foregroundof 000b and a background of 000b.

A White block is shown at 665Y. All the color signals 666Y, 667Y, 668Y,are on. The CRC for this character will be translated from each colorsignal to a block (ASCII hex DB). On this basis the bit values wouldyield: foreground: 111b background 111b.

A Yellow block is shown at 665Z. The blue color signal 668Z is off, orblack, and does not contribute anything and hence is translated to the“normal” CRC space character. The red 666Z and the green 667Z are on inboth the foreground and background to combine to make the solid YellowBlock. The CRC for this character will be translated to an ASCII valueof hex DB. On this basis the bit values would yield: foreground: 110bBackground 110b.

The ASCII hex 00 (null character) and ASCII hex FF characters areidentical (as displayed) to a solid block 666X, 666Y. Presently, thesecharacters are translated to a block (hex DB) character. The ASCII code00 is used to represent a character who's CRC is unknown (not in the CRClook-up table). This can occur for two reasons. One, when noise, orother transients corrupts the video signal, and two, when the presenceof the Host PC VDAC's hardware flashing cursor periodically obscures thecharacter. The ASCII code hex FF is defined as an invalid character andis used to clear (initialize) ASCII video data areas.

As discussed above, a “normal” character is defined as a foregroundcolor on black background such as 666F. Whereas an inverse or“highlighted”, character is defined as black on a background color suchas 666G. A character CRC will uniquely identify whether a particularcharacter is normal or inverse depending on whether the applicable colorsignal is translated to a character using the “normal” or “inverse”character set. When examining the red, green, and blue characters, eachcharacter can be one of the following ASCII codes: a space (hex 20)666X, a block (hex DB) 666Y, or the ASCII code of a particular character666F or 666G. So, in deriving the three bit foreground and backgroundcolor values, the process is as follows: for each particular color, ifthe character is a space, which is all black, then the foreground bitand background bit for this color are both set to zero. If it is acolored block character, then the foreground bit and background bit forthe color are both set to one. Otherwise, the character normal/inverseflag determines the setting of the color bit: normal sets the foregroundbit and inverse sets the background bit.

To determine a character code, if all three color characters are eitherspaces or blocks (such as 665X, 665Y, 665Z), then the character is ablock 665X. Otherwise, the character is any non-space, non-blockcharacter found (such as 665F). If there is more than one non-space,non-block character, they must be equal. If two such characters areencountered and are not equal, then the character is set to hex 00(unknown character). Also, if any color character is unknown(unrecognized CRC), then the resulting character is also set to hex 00.

The character comparison, to determine the differences, as referencedabove, include both the ASCII code as well as the color attributes. Ifforeground color changes from one character to the next, then this colorchange information is processed. If background color changes from onecharacter to the next, then this color change information is processed.If the character code changes, the new character will be processed.Blocks (ASCII hex DB) need special attention because they may beinterpreted as spaces depending on the foreground and background colorvalues. For instance, if White on Black text is being processed, such as665A, then the Black block 665X will be a space (hex 20) and the Whiteblock 665Y will be a block (hex DB). If however, Black on White text isbeing processed 665G, then the space 665X will become a block since theforeground color is black. Similarly, the White block 665Y will become aspace since the background color is White. This is determined byexamining previously processed character's color attributes. If theentire video screen is blank (all spaces being displayed) this may beinterpreted as 2000 spaces with Black background or 2000 blocks (Blackforeground). It does not matter, since they are equivalent. The onlyreason to differentiate spaces from blocks is for efficiency since onlythe ASCII code need be processed, rather than processing foreground andbackground information. Since typical screens are composed of asignificant amount of blank space, avoiding the need to processforeground and background information improves overall performance ofthe video signal translation process.

From the above discussion it will be clear to person of skill in the artthat the color attributes of the characters displayed on the Host PC VDMcan be interpreted and transmitted to a Remote PC using the presentinvention. The examples listed above are illustrative of the methodemployed by the present invention, which can be used to determine thecolor attributes of any characters displayed on the Host PC VDM.

When video text is first processed for remote access, the Current Screen663A is initialized to hex DB (the block character) and color attributes663B are initialized to zero (black foreground and background). Thesetwo data areas comprise the current text data captured and represent ablank screen. Each new captured text screen is then compared to thiscurrent screen data and only the differences are processed (i.e. eithersent to TVLINK.EXE or logged as history) and updated to the currentscreen data. Thus, by initializing the current screen data with hex DBand color attribute of zero, only the first non-blank video text datacaptured is guaranteed to be different, and thus be completelyprocessed. After this, only the differences will be processed. Theinitial text data and subsequent differences will be transmitted to theRemote PC via the Control CPU. Transmitting only changes over relativeslow speed telephone lines substantially reduces the amount of timerequired to transmit Host PC video display information to a Remote PC.Furthermore, using data compression techniques familiar to persons inthe trade further reduces the time needed to transfer data to a RemotePC.

To accumulate video text history, video text data is first captured andstored into the current screen 663A and the Base Screen 664A data areasas well as the color attribute data areas 663B, 664B. After newlycaptured text data is compared to the current screen data, only thedifferences are stored by the Accumulate History routine 623E in theHistory of Changes 664C data area and then updated to the current screendata. When the History of Changes data area 664C becomes full, theoldest changes are applied to the base screen 664A, thus freeing morestorage space 664C.

Some Remote users may wish to sacrifice color attributes for fastertransmission of text data. Presently, the remote user is given theoption (via the TVLINK.EXE program running on the Remote PC, discussedlater) to chose between one of the three color signals in lieu of colordetection using all three color signals, as previously described. Whenone color signal is selected, the Video CPU processes only that colorsignal and sends back normal and inverse video text data. In certaincases, characters may be formed solely by color signals other than onesignal selected. In these cases, the correct character cannot bedetermined. For example, a blue character on a black background will notbe detected on either the green or red color signals.

The Control CPU's keyboard interface emulates the Host PC's keyboard.Keyboard signals (either from the keyboard or the Control CPU) passthrough two stages before reaching the application program running onthe Host PC. The application program could include the DOS COMMAND.COMprogram. When any key is pressed and/or released, the keyboard sends oneor more serial data bytes to the Host PC. These bytes are processed by adedicated micro-controller within the Host PC, which translates thisinformation to scan codes, and asserts interrupt 9 to communicate to theHost PC's central processors (for example a 80386 microprocessor). Thisinterrupt invokes a BIOS routine which translates the scan code to anASCII (or extended) character code and places it in a buffer for use bythe current application. Although some application programs may bypassthe BIOS and service this interrupt directly, it will not affect theoperation of the present invention. Examples of extended character codesinclude the HOME, LEFT ARROW, and INSERT keys.

The keyboard uses a bi-directional synchronous serial protocol (8 bitplus parity) to communicate with the Host PC and the Control CPUemulates this interface when a Remote user is accessing a Host Unit.FIG. 5I shows the keyboard clock 671A and data 670A signals. Thesesignals are held at a logical high of 5 volts by a pull-up resistor. TheHost PC or keyboard asserts a logical low (0 volts) on these lines byuse of an open-collector driver. For each bit transmitted, data is firstasserted (high or low) (i.e. 670D) after which the clock is driven lowfor approximately 50 microseconds (i.e. 671C). The transfer of data iscontrolled by the keyboard, not the Host PC. That is, when clocking datato or from the Host PC, it is the keyboard which produces the clocksignal.

When a key is pressed, the keyboard sends a byte or bytes to the HostCPU. It first asserts a serial “start” bit 670B, asserts a clock pulse671B, then asserts the first data bit 670C, and so on, until the 8thdata bit 670E and parity 670F has been clocked. Then, a stop bit 670G isasserted with clock pulse 671D. This ends the byte transfer. At thistime, when the clock pulse is brought high 671E, the Host PC asserts alow on the clock line. This will remain low 671F until the Host PC hasfinished processing this data byte, at which time, the clock line willgo high 671G and the keyboard can send another byte. For keystrokes suchas, for example “A” through “Z”, 670A and 671A show the protocolinvolved, data flow is from the keyboard to the Host PC.

For keys such as CAPS-LOCK, NUM-LOCK, and SCROLL-LOCK, data flows bothways. That is, the Host PC controls the state of these functions. Whenthe NUM-LOCK key is pressed, for example, the keyboard sends thisinformation to the Host PC after which the Host PC sends the status ofall three functions which activate the NUM-LOCK, CAPS-LOCK, andSCROLL-LOCK indicators on the keyboard. The clock and data protocol forthis is shown at 672A and 673A. When the NUM LOCK key is pressed, thestart bit 672B and first clock 673B begins the byte transfer. After thebyte is transferred, the keyboard brings the clock line high 673C whichthe Host PC will immediately bring low again 673D to indicate busy.During this busy time, the Host PC brings the data line low 672C torequest a data transfer to the keyboard. When this happens, the keyboardwaits for the Host PC to set the clock line high again 673E at whichtime the keyboard now generates the clock pulses 673F. Note, that thedata signal at 672C also serves as the start bit. With each clocksignal, the keyboard shifts the Host PC's data 672D into its memory.When the transfer is done, the keyboard sets the clock line high 673Hand the Host PC brings it low again 673G to indicate busy. Whenfinished, the Host PC brings the clock line high 673J to indicate it isready for more keyboard data. If after the Host PC has brought the clockline low 673G and the Host PC has more data, the data line is againbrought low as illustrated at reference 672C and another data transfer,from the Host PC to the keyboard, will take place.

This concludes an overview of the clock and data protocol. Althoughone-byte transfers are described to explain the mechanisms forbi-directional data transfer, when a key is pressed, released, or for“lock” key activity (NUM-LOCK, etc.) multi-byte transfers are actuallyinvolved. Keys such as Print-Screen, Sys-Req, or CLT-Break also havetheir own multi-byte protocol. More detail concerning this operation isset forth in the microfiche appendix, part 7.

FIG. 6A illustrates the main training screen 681 presently generated bythe TVTRAIN.EXE program distributed with the apparatus. The sourceprogram code for the TVTRAIN.EXE program is included in the microficheappendix part 4.

Processing parameters needed to decode the video signals for a VDAC intodigital or text data may vary from VDAC to VDAC and may change furthershould VDAC technology change. The TVTRAIN.EXE program is invoked on theHost PC. The program permits the Host unit to decode the actual videooutput signals of a VDAC, including the video raster signals, againstknown data displayed on the screen to deduce the exact processing stepsrequired to decode the output of the VDAC. This approach permits theapparatus to process video regardless of the VDAC technology employed.These processing parameters are stored in the form of data tables storedin the Host Unit's non-volatile RAM, which are referenced by softwareprograms operating in the Host Unit Video CPU that decode the HostUnit's video signals. Once the TVTRAIN.EXE process has been successfullycompleted for a HOST PC, the process need not be repeated unless theHost PC's VDAC or VDM is changed or a new Host PC is connected to theHost Unit.

When the TVTRAIN.EXE is invoked on a Host PC, the Host PC waits for aspecific series of keystrokes to be received from the Host Unit to beginthe training process. Thereafter, the Host Unit controls the activitiesof the TVTRAIN.EXE program via keyboard input to the Host PC. After theTVLINK.EXE has been invoked on the Host PC, the “Action” button on thefront of the Host Unit must be pressed to instruct the Host Unit tobegin sending keyboard data to the Host PC. Thereafter, the Host Unitcontinues to control the TVTRAIN.EXE via keyboard input until thetraining process is complete. When training is in process the “SetupMode” indicator light on the front of the Host Unit blinks.

During the training process a video screen is presently displayed on theHost PC VDM as shown in FIG. 4A. This video display uses only black andgray or white unless otherwise noted.

The dashed horizontal line beginning at reference 683 shows 40 halfblock characters (hex DF) from the ASCII character set. Each of thesecharacters alternate with a space. The next solid horizontal linebeginning at reference 684 contains 80 half block characters (hex DF)forming a solid bar. The third vertical line beginning at reference 685through the twenty-fourth 687 row contain a hex B1 character in thefirst column (also shown enlarged at 680A. The twenty-fifth line (i.e.row) contains 80 characters (hex DC) as shown beginning at reference688.

As the first step in the training process, the horizontal and verticalsync polarities are determined and then the video processing circuitryis initialized to digitize the video data (the CRC configure latch 429is set to zero) by the Video CPU in the Host Unit. There are 8 pixelclocks per character and with 80 characters per row, a total of 640pixel clocks are needed. Each of these pixel clocks is initialized to asmall default value to place them approximately 25 nanoseconds parts.

Then, to determine whether the video signal is analog or TTL, the greenanalog signal is selected and video is captured. The video data is thenscanned for black and white activity which will be found when datarelating to 683 is encountered. If the data is all zeros or all hexFF's, then the monitor is not analog and the TTL green signal will beselected, and video activity checked again. If video is still notdetected, then the Video CPU instructs the Control CPU to send akeystroke to the Host PC, via the keyboard interface, instructingTVTRAIN to display an error message. Otherwise, the video trainingprocess continues.

Next, a video screen is captured. First, the number of non-displayablehorizontal scan lines 682 must be determined. This is done by countingeach 80 byte (one scan line) until a non-blank scan line is found (i.e.reference 283). Second, starting with the first non-blank scan line 683,scan lines are counted, until the next horizontal line (i.e. reference684) is encountered. This gives the number of horizontal scan linesneeded to generate a character.

With this information, the training process continues to capture thevideo, ignoring the first two rows 683, 684 and begins adjusting thepixel clock timings using the columns in the vertical line between 685through 687. This column 685 is shown in more detail at 680A. The blankspace referenced at 680B shows the first pixel of the character hex B1.The black square referenced at 680C shows the first pixel of the nextscan line. The series of blank and black squares referenced by 680Dshows the first character in it's entirety. In a VGA mode 16 horizontallines are needed to make the character. The next Character referenced at680E immediately follows the first character thus supplying an unbrokenseries of alternating pixels (i.e. 680B, 680C, and downward). Thevertical column of hex B1 characters indicated by 685 to 687 include 352horizontal scan lines for VGA text mode video (16 scan lines by 22rows). For some monochrome adapter cards using 8 scan lines percharacter row, there are only 176 scan lines. In any case, 100 scanlines of the column 685 to 687 are used in the training process.

FIG. 6B shows the first four horizontal scan lines of 680A andassociated data streams. The pixel referenced at 680B is shown again atreference 690B. The 8 character pixels starting with 690B is shown as adata stream at 690F. Similarly, 690C is shown at 690G, 690D is shown at690H, and 690E is shown at 690J. Pixel clocks positioned correctly areshown on the line beginning at reference 690K. Correct positioning iswhen, the pixel clock will reliably capture pixel data without errorsdue to jitter. Pixel clock 690M captures the first pixel or data bit,the following 7 pixel clocks captures the remaining 7 pixels, producinga data byte for each scan line. The value of this byte for 690B, 690F is55 hex or 01010101 binary. The value of the next byte for 690C, 690G isAA hex or 10101010 binary. The first pixel is the Most Significant Bit(MSB) of the resulting byte value.

Note that as shown, the first pixel 680B of the character hex B1 is azero data bit and that 680C is a one data bit. For some video adaptercards however, the hex B1 character is reversed. That is, the firstpixel 680B of the character hex B1 is a one data bit and that 680C is azero data bit. Since the Host Unit knows the expected character contentsof each screen location, the Host Unit can automatically detect thisreversal, which illustrates how the apparatus can automatically adaptitself to diverse VDACs through this training process.

A primary subroutine involved in the training process evaluates thecorrectness of a pixel clock position in relation to the video pixeldata. This routine processes 100 scan lines. Each scan line is digitizedto 80 bytes, each byte representing one scan line of a character. Beforecalling this subroutine an INDEX and a MASK value is set. The INDEXselects one of the 80 bytes across the screen. The INDEX starts at zero,which is the left most column, moves across the screen one column at atime and ends at 79, which is the right most screen column 689B. TheMASK selects one of the bits within a byte referenced by this INDEX.Reference 690R show a table of these MASK values.

As the first step in this subroutine, the pixel at 690B is tested. If itis zero, then a COUNTER is incremented. Then the pixel at 690C istested. If it is nonzero, then a COUNTER is also incremented. This isrepeated for pixels 690D, 690E, and so on, testing for alternating pixelvalues, until 100 pixels have been tallied. The value of the COUNTERshould now equal 100 and, if so, then the pixel clock 690M is correct.If it is less than 100, then the pixel clock needs to be repositioned,and the pixel column 690B rechecked.

After pixel clock 690M is positioned correctly, then pixel clock 690N isselected. At this point, the first pixel in this pixel column (to theright of 690B) will be a one instead of zero at 690B.

Initially, the INDEX for the pixel clock referenced at 690M is set tozero and the MASK is set to hex 80. After the pixel column is processedand the COUNTER equals 100, then the MASK is shifted right to become hex40, to test 690N, then it is set to hex 20 for 6900, and hex 10 for6900, until the eighth pixel column is processed with the MASK equal tohex 01. The eight pixel clocks for this column of characters (i.e. 685to 687) are now positioned.

The Video CPU now instructs the Control CPU to send a keystroke to theHost PC, via the keyboard interface, which instructs the TVTRAIN.EXEprogram to move the column of hex B1 characters 685, 687 over to thenext column at 689A. The training process now increments the INDEX byone and sets the MASK to hex 80, and proceeds to position the next 8pixel clocks 690Q. This process is repeated until the last column at689B has been processed (INDEX equals 79). The pixel clocks nowcorrectly capture the 640 pixels.

When the horizontal scan line begins 690A, there is a blank area or leftmargin 686 before visible pixels commence. When attempting to positionthe first pixel clock at 690M, it may be at 690L or some other location.Notice here that the data streams 690F, 690G, 690H, 690J and so on, willall have a value of zero. So when the subroutine, described above,processes this data, the value in COUNTER will be 50 since only half thepixels are of the correct value. That is, they are all zero whereas thesubroutine expects alternating pixel values. On this basis, the trainingprocess permits the unit to automatically adjust to the blank areaspresent for a given VDAC by skipping over situations where the verticalpixel counter is 50.

Signal interference or noise may cause minor distortions during thetraining process in the pixel COUNTER. Therefore, a tolerance of plus orminus 3% is presently permitted when setting the pixel clocks. Inaddition, in cases where a pixel clock appears to be out of suchexpected ranges, processing for the pixel clock is automaticallyrepeated up to 10 times to resolve the problem. If the problem cannot beresolved at that point, the training process is terminated and an errormessages is displayed suggesting that another VDAC or Host Unit be used.

FIG. 6C shows the effect of pixel clock timing on the COUNTER value.Waveforms 692A and 692B show several pixels from two scan linesincluding jitter 692M. Waveforms 692C, 692D, 692E, 692F, 692G, 692H,692J show the pixel clock pulse of 690N at different timing positions.This pixel clock as shown at 692H is correctly positioned for 690N. Thepixel clock shown at 692C is actually positioned at the previous pixel690M, 690B, 690C. The COUNTER value resulting from this clock pulse willbe zero because none of the pixels are correct. As explained, pixelclock 690N expects a consistent pixel value of one 692K followed by apixel value of zero 692L.

At 692D, the COUNTER value will be approximately 10 because, due tojitter, the pixels will be correct 10 percent of the time.

At 692E, the COUNTER value will be approximately 50. At 692F, theCOUNTER value will be approximately 90. At 692G, the COUNTER value willbe close to 100 (due to insufficient data setup time requirements). At692H, the COUNTER value will be 100. At 692J, the COUNTER value willagain be close to 90.

After the pixel clock timing has been determined, the Video CPUinstructs the Control CPU to send a key stroke to Host PC, via thekeyboard interface, instructing TVTRAIN.EXE program to display thecharacter set as shown on FIG. 6D. Both normal and inverse (highlighted)characters are shown. At this time, the Video CPU enables CRC generationby setting the CRC configure latch 429 to the value of hex 83 (whichwill select the two least significant bits and the most significant bitof the shift register 439, for feedback 426).

The video is then captured producing CRC's for each character shown onFIG. 6D. Presently there are 512 possible characters (256 normal, 256inverse) that may be displayed on an Host PC's VDM operating in a textmode. Some of these characters are duplicates. For instance, the zeroASCII code, or null character at 698A, and the hex FF character 698Cdoes not display on a VDM and is the same as the space character 698B,and will be interpreted as a space (hex 20). Similarly, the blockcharacter (above the square root sign and near 698C) is identical to theinverse null 698D and an inverse space 698E, and will be interpreted asa block. Although, the ASCII codes differ among these two sets ofcharacters, the visual information is identical.

Only the CRC's for the character sets on FIG. 6D are presentlyprocessed. First, they are checked for uniqueness (ignoring duplicate oridentical characters). If they are not unique, then a new value must bewritten to the CRC configure latch 429, such as hex 85, etc. The videois again captured and the uniqueness test is repeated. When a suitablevalue for the CRC configure latch, which provides for unique CRC codesfor all characters is found, video training continues.

If the VDAC is analog (not TTL) then the Video CPU instructs the Controlto send a key stroke to Host PC, via the keyboard interface, instructingTVTRAIN.EXE to enter a 16 color 640 by 480 graphics mode and display asingle horizontal bar at the top of the screen. The horizontal andvertical sync polarities are determined for this mode and then the videoprocessing circuitry is initialized to digitize the video data (the CRCconfigure latch 429 is set to zero). The number of horizontal scan lines682 preceding any visible pixels is then determined.

All information gathered during this video training process includingthe pixel timing information and character CRC's are transferred to theControl CPU for storage in non-volatile RAM. A flag in non-volatile ramis then set to indicate the Host Unit has been successfully trained andthe SETUP indicator light 54 is turned off.

When the training process is complete, the Video CPU instructs theControl CPU to send a keystroke to the Host PC, via the keyboardinterface, informing the TVTRAIN.EXE program that training wassuccessful. At this point the Host PC returns to it's normal operatingsystem (e.g. DOS).

FIG. 7 is a block diagram describing the software processing presentlyoccurring within a Remote PC. Rectangular objects on this diagramrepresent software subroutines or menu displays that may be initiatedwithin the Remote PC's CPU whenever a program (herein referred to asTVLINK.EXE) supplied as part of the apparatus is executed. Diamondshaped boxes represent major processing decisions occurring within theTVLINK.EXE program. Circled boxes with letters inside represent eitheron-page or off-page connectors to the next processing step in the blockdiagram. Lines with arrows represent the direction that TVLINK.EXEprocessing flows.

Source program code presently used for TVLINK.EXE is contained in part 3of the microfiche appendix. TVLINK software is installed on each RemotePC that will access Host Site(s).

TVLINK.EXE processing begins at block 700 on FIG. 7A. When the programis first invoked, a System Main Menu is displayed 701 with threeprocessing options. The first menu option, Setup System 702, permitsconfiguring the system to the user's specific requirements and thehardware configuration of the Remote PC where the system is beinginstalled. The second menu option “Call Host Site” 703 permits the userto cause their Remote PC to call and link to a desired Host PC. Whenthis menu option is selected, a call list of Host Units that may beselected is displayed 704. This call list is created and maintained aspart of Setup System 702 processing. When a Host Unit on the list isselected, the program initiates linkage processing to the selected HostSite, then links to the requested Host Unit. Once linked a password isrequested by the Host Unit using a password transmission key basedrandom number that causes the password transmitted by the Host Unit tobe encrypted following a procedure set by the key. This approach makesit difficult for someone to decode a password being transmitted from aRemote PC to a Host Unit by tapping into the communication line. If aninvalid password is received by the Host Unit, a “session” lock outcounter for the Host Unit is incremented by one. If this counter exceedsthe limit set for the session (see block 734 processing below), the useris locked out from any further access attempts to the Host Unit for thecurrent session and a Host Unit lock out counter stored in non-volatileRAM in the Host Unit is incremented by one. If the Host Unit lock outcounter exceeds the limit for the Host Unit (see block 734 processingbelow), all access to the Host PC will be blocked until someone pressesthe Action button on the front of the Host Unit.

If a connection is made to the selected Host Unit 705, the TVLINK.EXEprogram pops up a menu on the screen with two choices permitting theRemote user to either select a normal access mode or a view only accessmode. In a normal access mode, the user has full keyboard and videoaccess to the Host Unit. In a view only access mode, the user has onlythe capability to view the output of the Host PC's VDAC. Next,processing continues at block 742. If the Host PC is not turned ON orthe Host Unit is not properly connected to the Host PC, the Host Unitwill return an error that no Host Video signal is present, but theconnection to the Host Unit will continue until terminated by the RemoteUser for the possible purpose of retrieving any VDAC screen history thatmay be present in the Host Unit.

If a connection cannot be completed to a Host Unit 705, an appropriateerror message appears on the Remote PC VDM screen indicating why theconnection could not be completed and the System Main Menu 701 isredisplayed. The final System Main Menu option, Exit System 708terminates TVLINK.EXE program processing and returns control to theRemote PC's operating system.

When TVLINK.EXE program is executed for the first time on a Remote PC,the Setup System 702 main menu option is selected first to (1) definewhether the linkage to a Host PC will be in a Modem Linkage mode orDirect Line Linkage mode; (2) setup the Modem Specifications andparameters 711 to initialize and access the modem connected to theRemote PC in those cases where a Modem Linkage mode will be used; (3)setup the Mouse Specifications and parameters 713 to define the RemotePC's serial port number where the Remote PC's mouse is connected inthose cases where a serial mouse is present on a Remote PC and will beused to control a Host PC; and (4) setup the CALL LIST 715 of Host Unitsthat may be accessed by the Remote PC 715. After these initial setupoptions have been completed, the Setup System 702 menu option may beselected to setup other system configuration options or to re-configureany options previously entered.

When selected, the Setup Main Menu 710 displays a list of four options.The Modem Specifications 711 menu setup option allows the baud rate,serial communications port number and modem initialization string to bedefined for the modem connected to the Remote PC. If the Remote PC willonly operate in a Direct Line Linkage mode, then the modeminitialization string would not be entered.

When this option is selected, the software 712 automatically searchesfor a Hayes compatible modem connected to one of the serial ports on theRemote PC. If the modem does not respond to the search, the modem'spower is turned off (external modem), the cable between the Host Unitand modem has not been properly connected (external modem), or a serialinterrupt conflict prevents access to the modem, the Setup process willassume that the Direct Line Linkage mode will be used.

After the Modem Specifications are entered or modified, this informationis saved on the Remote PC's mass storage device. After the baud rate andmodem reset string are set to desired values, the Esc key may be pressedto return to the Setup Main Menu 710. When the Esc key is pressed andthe Modem Linkage option is specified, the software automaticallyinitializes the Remote PC's modem using the baud rate and reset stringspecified. Thereafter, whenever the TVLINK.EXE program is firstinitiated, the modem installed in the Remote PC is initializedautomatically, so there is no need to re-run this menu option againunless the modem installed in the Remote PC is changed or the modem doesnot properly connect with a Host Unit. Once all required modificationhave been made to the Modem Specifications, the Esc key may be pressedto return to the SETUP menu.

The Mouse Specifications menu option 713 permits specifying the RemotePC's serial port to which a mouse is connected. If no serial port numberis specified, the TVLINK.EXE software assumes that a mouse is notinstalled on the Remote PC. Otherwise, the TVLINK.EXE program tests forthe presence of a mouse on the specified serial port and displays anerror message, if the mouse cannot be found by the TVLINK.EXE software.Once a valid serial port is specified, the port number selected is savedto a configuration file on the Remote PC's mass storage device, so thatsubsequent TVLINK.EXE sessions will know if and where a mouse has beeninstalled on the Remote PC. Once all required modifications have beenmade to the Mouse serial communications port, the Esc key may be pressedto return to the SETUP menu.

The Update Call List 715 menu option permits each Host Unit that aRemote PC may access to be defined or changed 716. Before a call can beplaced to Host Unit, the Host Unit must be defined in the Remote PC'scall list.

The specific data elements that presently must be defined for each HostUnit to be accessed include: (1) a location description, which is a userdefinable alphanumeric description of the Host Unit being accessed suchas “SERVER XYZ”, “VAST TAPE Unit”, etc. (such descriptions help userswith access to multiple Host Units more easily select a desired HostUnit); (2) a dialing string needed to call and access the modem at thesite where the Host Unit is located in cases where the Remote PCoperates in a Modem Linkage mode; (3) an alphanumeric password thatallows only authorized persons who have the password to access aspecific Host Unit; and (4) the ID number of the Host Unit to beaccessed.

When a Host Unit is first installed, the default password has beenpreset prior to shipment to the eight digit serial number of the HostUnit, located on the label affixed to the bottom of the Host Unit. Thisnumeric password must be specified in the Remote PC used to initiallyaccess an newly installed Host Unit. After a Host Unit has beensuccessfully accessed using a correct password, the password may bechanged as described later for block 734.

New call list entries may be added by using the Remote PC's down arrowkey to go to the: last line of the call list which will be a blank linepermitting the entry of data for the new Host Unit to be accessed.

An entry may be deleted from the call list by using the Remote PC'skeyboard up or down arrow keys to highlight the applicable line item andthen pressing the F3 key to delete the line from the call list.

A call list entry may be changed by highlighting the applicable lineitem, then changing the data contained on the line, as desired. Variousother keys may be pressed to speed the process of navigating through acall list. A list of these keys is displayed in a pop up window wheneverthe user presses the F1 key. The pop up window is removed from screenwhen the user presses the Esc key.

Once all required modifications have been made to the call list, the Esckey may be pressed to return to the Setup Menu.

The last menu option on the Setup Main Menu 710, Return To Main Menu719, permits returning to the appropriate System Main Menu VDM screen asdiscussed below beginning at block 742.

The “Connection Options” menu line only appears on the Host System MainMenu 755 when a active linkage exists between the Remote PC and a HostUnit. When selected the Connection Options Main Menu 720 is displayedthat presently contains various processing options.

The Scan Screen History 721 connection menu option permits Host VDMscreen data captured and transmitted to a Remote PC's VDM during alinkage session to be reviewed 722.

When the Remote PC is linked with a Host PC, all video VDM screen datareceived from the Host Unit is automatically logged to a screen historydata file on the Remote PC presently called SCRNHIST.DAT. This file isautomatically cleared whenever TVLINK.EXE processing is first initiated.

When the Display Screen History connection menu option is selected, theTVLINK.EXE program automatically activates a VIEWHIST.EXE subroutine toview the SCRNHIST.DAT file for the current TVLINK.EXE processingsession. This permits any VDM screen data captured since the TVLINK.EXEprogram was initiated to be reviewed. The VDM screen history can bereviewed by using the UP and DOWN arrow keys. The Esc may be pressed toreturn to the Connection Options main menu 720.

The Color Mode 723 connection menu option is selected to set the activeHost Unit to a specific color or monochrome display mode for purposes ofcapturing VDAC output for transmission to a Remote PC.

Five menu options are displayed when the Color Mode 723 menu option isselected, which are (1) Normal Color Mode, (2) Bright Color Mode, (3)Green Signal Mode, (4) Red Signal Mode, and (5) Blue Signal Mode. Thesemenu options give a Remote user the ability to either transfer VDAC textoutput to a Remote PC in normal intensity or high intensity color or ina monochrome mode using either the Red, Blue or Green signal as thebasis for decoding the VDAC output. In the high intensity color mode,the foreground colors are displayed from the high intensity color setand the background color set remains normal.

Normally the Host Unit is in a default display mode where the HostUnit's Video Processor only looks at the green color signal output ofthe VDAC. This mode is one of three possible monochrome modes andnormally yields the fastest possible video processing and the greatestprobability of decoding video text data displayed by a color VDAC andthe green signal is the only signal for some monochrome VDAC output.Blue and Red Signal Modes also yield the fastest possible videoprocessing, but selecting these modes may cause a lower probability ofdecoding either the Blue or Red signals into characters because Host PCcolor applications typically use the Blue or Red signals less often thanthe green signal.

Selecting either the Normal or Bright Color Modes slows down the VideoCPU which must decode multiple signals in order to determine color andthe text character. As a result, text data may not appear as quickly ona Remote PC, when either color mode is selected. However, selectingcolor assures the highest probability that the text data output of aVDAC will be properly decoded.

Presently, for graphics modes only the green VDAC output signal is usedregardless of the menu option selected. As previously mentioned addingadditional hardware to the Host Unit's Video Processor circuitry wouldpermit multiple color graphics transfers to a Remote PC in a reasonableperiod of time.

The UP and DOWN arrow keys may be used to change to a desired color ormonochrome display mode and then the Enter key may be pressed to selectthat mode.

After the desired display mode option is selected off of the menu or theESC key is pressed, processing is returned to the Connection Optionsmenu 720.

The Switch Host/Remote Mode 725 connection menu option is selected toset the mode that will be active after exiting from the main system menuwhen a connection to a Host Unit is active. Whenever TVLINK.EXEprocessing is first initiated, Host mode processing is assumed.

A menu 726 containing two possible modes appear when the SwitchHost/Remote Mode 725 menu options is selected. The desired mode ishighlighted using the Up and Down keyboard arrow keys and then the Enterkey is pressed to select the mode.

If the Remote menu option is selected, the last menu option on thesystem main menu will be changed from “Exit to Host mode” to “Exit toDOS” after exiting from the Connection Options Main Menu 720. On thisbasis, selecting Exit to DOS option causes Remote PC processing totemporary exit out of the TVLINK.EXE application to the PC's operatingsystem (e.g. DOS) while continuing to maintain a connection to the HostUnit. Once DOS processing has been completed, a user may then return tothe system main menu by typing “EXIT” at a DOS prompt. For example,shelling-out to DOS during a TVLINK.EXE session would be useful if itbecame necessary to locate the directory where a file is located inorder to transfer the file to a Host PC.

If the Host menu option is selected, the last menu option on theTVLINK.EXE menu will be “Exit to Host mode”. When a Remote PC is placedin a Host mode, the Remote PC assumes control of the Host PC. In thismode, the contents of the Remote PC's VDM screen reflect the contents ofthe Host PC's VDM screen and the Remote PC's keyboard and mouse(assuming the mouse option is installed) is redirected to inputkeystrokes/mouse data to the Host PC, as opposed to the Remote PC.Accordingly, because the Remote keyboard, mouse and VDM act as if theremote user is sitting at the Host PC, there needs to be a sequenceand/or combination of keystrokes (i.e. hot key) pre-defined that willcause the Remote PC to return back to a normal operating mode.Presently, tapping the left Shift key three times within 2 seconds actsas this hot key causing the Remote PC to return back to a normaloperating mode. In this same regard, if a user taps the right Shift keytwo times within two seconds while in a Host mode, it will refresh theRemote PC's VDM screen by causing the Host Unit to transmit the entirecurrent contents of the Host PC's screen. Normally, the Host Unit onlysends any changes that have occurred on the Host PC's screen to minimizethe amount of data transmitted to a Remote PC. On occasion, variances inthe Host PC's VDAC signals may cause the Host Unit to misinterpret datadisplayed on a screen and send corrupted display data to a Remote PC.Tapping the right Shift key twice refreshes the Remote PC's VDM screen.

Normally, when a Remote PC is in a Host mode, all key strokes enteredinto the Remote PC's keyboard are intercepted by the TVLINK.EXE programand transmitted to the Host Unit, so that the Host PC can pass thesekeystrokes on to the Host PC. This process also permits the TVLINK.EXEto take other actions when necessary. As previously mentioned, multipletaps of the left or right shift keys presently cause the TVLINK.EXEprogram to pop up and activate TVLINK.EXE menu processing. In addition,when the “Print Screen” key is pressed, TVLINK.EXE presently permitsthis keystroke to pass through to the Remote PC's operating system,thereby permitting the Remote PC to print the contents of a Host PC'sVDM screen to a printer connected to the Remote PC. Other suchprocessing exceptions can be made where necessary (through appropriatechanges to the TVLINK.EXE program code) to further enhance a Remoteuser's ability to more effective manage both their Remote PC's and HostPC's resources.

When a user is in a Host mode and presses the left Shift key three timeswithin two seconds, the user is returned to the System Main Menu 741.This menu and other menus pop-up (i.e. overlay) over a portion of theHost PC's screen. Any Host VDM information displayed continues to beupdated and visible behind the pop-up menu on the Remote PC's VDM screenuntil the Host PC's connection is terminated or the user temporarilyexits to the PC operating system (e.g. DOS) as explained at blocks 753and 754.

After either the Host or Remote option is selected, processing isreturned to the Connection Options menu 720.

The File Transfer 727 connection menu option is selected to permit datafile transfers to occur between the Host PC and Remote PC. Filetransfers from one directory location on a Remote PC to anotherdirectory location on the Remote PC can be accomplished by temporarilyexiting to the PC's operating system, as described under the narrativefor block 726 above. File transfers from one directory location on aHost PC to another directory location on the same Host PC can beaccomplished by selecting the “Exit to Host” option off of the systemmain menu, then using the Remote keyboard (that has been redirected tooperate in place of the Host PC's keyboard) to complete the transferusing, for example, the DOS COPY command.

In order to complete any file transfer between a Host and Remote PC, theHost Unit must have been properly connected to one of the Host PC'sserial ports. When this file transfer option is selected, a menucontaining two options appears that define the direction of the filetransfer 728. The first option permits file transfer to occur from theRemote PC to the Host PC. The second option permits file transfers tooccur from the Host PC to the Remote PC. File transfer processing may beaborted by pressing the Esc key. If the Esc key is pressed, processingwill return to Connection Options Menu 720.

Once the direction of the file transfer has been selected, the entry ofthe file specification is required to define the file(s) to be copied.This specification is presently set to follow the normal DOS COPYcommand format used to describe a source file to be copied. For example,the source file could be specified as C:\NETWARE\*.EXE, C:VREPAIR.COM,or \NETWARE\VREPAIR.COM. Once the source file has been specified, theentry of the target drive and full directory path where the files willbe copied is presently required.

After the source files and target location have been specified, filetransfer processing is initiated automatically using a file transferprotocol such as XMODEM, which is known to persons familiar to thetrade. File transfer processing is aborted if (1) the Esc key ispressed, (2) no source files exist or the source file drive and/ordirectory is invalid, (3) the Host Unit is not properly connected to anactive, available, Host PC serial port, or (4) the target drive and/ordirectory do not exist. Should processing be aborted an appropriateerror message will be displayed and processing will return to theConnection Options Main Menu 720. Otherwise, during the file transferprocess, the name of each file being transferred will be displayed.

After a desired file transfer process has been completed, processing isreturned to the Connection Options Main Menu 720.

The Cold Boot Host 729 connection menu option is selected to temporarilyinterrupt all AC power to the active Host PC for approximately 15seconds. A Host PC cannot be cold booted unless the Host PC's AC powerplug is plugged into the AC Out receptacle on the back of the Host Unit.

When this menu option is selected, the cold-boot request must beconfirmed by entering “Y” in response to the question “ARE YOU SURE?(Y/N)” 730. If “N” is entered in response to the question, cold-bootprocessing is aborted and processing returns to the Connection OptionsMain Menu 720. If “Y” is entered, the Remote PC sends instructions toHost Unit to temporarily cut AC power to the Host PC for approximately15 seconds. Once the power is restored, the Host PC reboots, the HostUnit returns a confirmation to the Remote PC that the cold boot processhas been completed and processing returns to the Connection Options MainMenu 720.

The Switch To New Unit 731 connection menu option is selected to switchfrom one Host Unit on a daisy chain to another Host Unit on the samedaisy chain without terminating the linkage between a Remote PC and aHost Site.

If only the currently active Host Unit at a Host Site is accessible,there is no reason to select the Switch To New Unit menu option. Incases where it is desired to switch from one Host Unit to another HostUnit at a different Host Site, the currently active modem linkage mustbe terminated by selecting the Terminate Call menu option 737, thenestablishing a new connection to the desired new site, as describedbeginning at block 703.

When the Switch To New Unit 731 option is selected, a call listcontaining all Host Units defined using the same phone dialing string isdisplayed 732.

The list of Host Units are displayed to permit switching between HostUnits daisy chained together without the need to terminate the existingphone line connection. The Esc key may be depressed to avoid switchingto another Host Unit and return to the Connection Options Main Menu 720.The UP or DOWN arrow keys can be used to scroll through the list of HostUnits defined. Once the desired Host Unit has been highlighted, theEnter key can be pressed to switch to the new Host Unit.

If the new Host Unit is inaccessible or the password used for the newHost Unit is incorrect, an appropriate error message will be displayedon the Remote PC's VDM screen, the connection to the last active HostUnit will be restored and processing will return to the ConnectionOptions Main Menu 720. Otherwise, the active connection will be switchedto the requested Host Unit and processing will be returned to theConnection Options Main Menu 720.

When the Change Unit Password option is selected 733, the systemrequests the entry of a new password for the currently active Host Unit734. The Change Unit Password option permits changing the currentlyactive Host Unit's password to a new password. When the password ischanged, the call list entry for the applicable Host Unit isautomatically updated to reflect the new password. Presently, when aHost Unit is manufactured, the password is initially set as the HostUnit's serial number.

When the Change Unit Password option is selected, the user is requestedto enter a new password of up to eight digits in length. Password changeprocessing may be aborted by pressing the Esc key. When the Esc key ispressed, processing returns to the Connection Options Main Menu 720.Otherwise, after a new password is entered, the Host Unit is updated forthe new password.

After the password has been updated, the user is requested to enter anychanges to the number of attempts during a session that a user is givento enter a valid password before being locked-out of this Host Unit forthe session. An entry of zero indicates that a user may be given anunlimited number of attempts to enter a valid password to access theHost Unit. For purposes of lock out processing, a session refers to theperiod between when a remote user first connects to a host site untilthat time the remote user terminates the connection to the site.

Once the number of password attempts during a session has been updated,the user is requested to enter the number of concurrent sessions thatmay occur where a user fails to specify a correct password whenaccessing this Host Unit and is locked out of the Host Unit for thesession. If the number of concurrent access lock-ups exceeds thespecified number, the Host Unit will be electronically locked, untilsomeone presses the action button on the front of the Host Unit. When aHost Unit is electronically locked, any user attempting to access theHost Unit will be given a message that the Host Unit was locked due to apossible intruder and access will be denied even if a valid password isentered until the Action button on the front of the Host Unit ispressed. Also, when a Host Unit is electronically locked, the Host Unitwill emit a periodic audible alarm sound indicating the Host Unit islocked until the action button on the front of the Host Unit is pressed.An entry of zero indicates that the Host Unit should never beelectronically locked. Whenever a Host Unit is successfully accessed bya Remote user, the concurrent session lockout counter is reset to zero.

Both the session lock and electronic lock are security measures designedto prevent giving a means to unauthorized intruders to guess a passwordto a Host Unit by limiting the number of guesses they can make andbringing the unauthorized access attempts to the attention of managementvia the electronic lockout procedure.

After, the password and related access counts are entered, theapplicable call list entry is updated to reflect the new password, andprocessing returns to the Connection Options Main Menu 720.

When the Change Temporary Password option is selected 735, the systemrequests the entry of a new temporary password for the currently activeHost Unit 736.

In some cases it may be necessary to grant someone temporary accessrights to a Host Unit. For example an independent network consultant ata remote site may need to temporarily access a file server to fix anunusual network problem.

When the Change Temporary Password 735 menu option is selected, a usermay specify an additional “temporary” password and a number of hoursthat the password should remain in effect. The temporary password entrymay be aborted by pressing the Esc key. If the Esc key is pressed,processing returns to the Connection Options Main Menu 720. Otherwise,after a new temporary password is entered, the Host Unit is updated forthe new temporary password, number of hours the password will remain ineffect, and then processing returns to the Connection Options Main Menu720.

The Terminate Call 737 connection menu option is selected to terminatethe linkage to a Host site. When Terminate Call 737 menu option isselected, the call termination request must be confirmed by entering “Y”in response to the question “ARE YOU SURE? (Y/N)” 738. If “N” is enteredin response to the question, call termination processing is aborted andprocessing returns to the Connection Options Main Menu 720. If “Y” isentered, the connection to the Host site is terminated causing both theHost and Remote modem to be reset, when in a Modem Linkage mode, andprocessing returns to the System Main Menu 701.

The Clear Screen History 739 connection menu option is selected to clearall screens captured and stored on the Remote PC's mass storage devicesince TVLINK.EXE processing was initiated or the screen history file waslast cleared during an active session.

When the Clear Screen History 739 menu option is selected, the clearscreen history request must be confirmed by entering “Y” in response tothe question “ARE YOU SURE? (Y/N)” 740. If “N” is entered in response tothe question, clear screen processing is aborted and processing returnsto the Connection Options Main Menu 720. If “Y” is entered, the screenhistory file is deleted, a new empty screen history file is created andprocessing returns to the Connection Options Main Menu 720.

The Select Mouse Mode menu option 740A connection menu option isselected to activate or deactivate recognition of a mouse connected tothe Remote PC. When this menu option is selected, two menu optionsappear 740B permitting the user to instruct the TVLINK.EXE software toeither recognize or ignore mouse movements from the mouse connected tothe Remote PC for purposes of transmitting the mouse movement data tocontrol the Host PC.

The Return To Main Menu 741 connection menu option is selected to returnto the system's main menu or is automatically invoked if the connectionto a Host Unit is lost. The processing options displayed on the system'smain menu vary depending on the processing status and the Remote/Hostmode status 726. If a connection between a Remote Site and a Host siteis lost due to a communications failure during connection options menuprocessing 742, processing returns to the System Main Menu at block 701.Otherwise, if the system is in a Host mode 743, Host Mode Main Menuprocessing is initiated beginning at block 755. If the system is in notin a Host mode 743, Remote Mode Main Menu processing is initiatedbeginning at block 750.

Remote Mode Main Menu processing begins at block 750. This menu includesthree processing options. If the Setup System processing option 751 isselected, Setup Main Menu processing begins at block 710. If theConnections Main Menu option is selected 752, connection optionprocessing begins at block 720. If the EXIT TO DOS option is selected753, control is returned to the PC's operating system (e.g. DOS,Windows™, etc.) until the Remote user key enters “EXIT” 754. After theuser enters “EXIT” processing returns to the Remote Mode Main Menu 750.

Remote Mode Main Menu 750 processing is terminated automatically if thecommunication connection between a Remote PC and a Host PC is lost 754A(e.g. due to a phone line failure) and processing is returned to theSystem Main Menu 701. Otherwise, Remote Mode Main Menu processingcontinues until either the Host Unit connection is terminated 738 or themode is switched to a Host mode 726 during Connection Options Main MenuProcessing 720.

Host Mode Main Menu processing begins at block 755. This menu includesthree processing options. If the Setup System processing option 756 isselected, Setup Main Menu processing begins at block 710. If theConnections Main Menu option is selected 757, connection optionprocessing begins at block 720. If the Exit To Host Mode option isselected 758, the Remote PC's keyboard, mouse (assuming a mouse isinstalled on the Remote PC and activated as described at block 740B) andVDM display are redirected to control the Host PC's keyboard/mouse anddisplay the Host PC's video output 761 until the Remote user taps theleft Shift key three times within two seconds, as previously discussedat block 726. When the user taps the left shift key 3 times, processingreturns to the Host Mode Main Menu 755.

When a Remote PC is in a Host Mode the Remote PC's screen modeautomatically switches to the screen mode (e.g. text or graphics)presently active on the Host PC. If the active screen mode is notsupported by the TVLINK.EXE program or the Remote PC's VDAC, a errormessage indicating the Host PC has an unsupported video mode appears onthe Remote PC. If during the course of accessing a Host PC, the screenmode should change, the Host Unit would automatically notify the RemotePC that a change has occurred to a new video mode and then wait for aresponse from the Remote PC to confirm the Remote PC VDAC has beenswitched to the new video mode before further video data transfersoccur.

Host Mode Main Menu 755 processing is terminated automatically if thecommunication connection between a Remote PC and a Host PC is lost 760and processing is returned to the System Main Menu 701. Otherwise HostMode Main Menu processing continues until either the connection isterminated 738 or the mode is switched to a Remote mode 726 duringConnection Options Main Menu Processing 720.

FIGS. 8A and 8B show examples of the current protocol implementedbetween the Host Unit and the TVLINK.EXE program running on a Remote PC.Numerous alternative approaches known to those of skill in the art couldhave been chosen to implement a protocol for the apparatus.

Values used in the protocol are shown as hexadecimal numbers. Initially,once a modem connection has been established between the Remote PC andthe Host Unit 00, all Host Unit's at a site constantly monitor data fromthe TVLINK. EXE program waiting for a correct access request addressedto their Host Unit's ID.

Reference 807 represents data which the TVLINK.EXE program sends to theHost Unit. Reference 806 represents data which the Host Unit sends tothe TVLINK.EXE program. The TVLINK.EXE program accesses a given HostUnit by sending a four byte packet as shown at references 800, 801. Thefirst two bytes (hex 70 and hex 00) indicate that access is requested,and is followed by two bytes which contain the requested unit'sidentification number. This number is split into two 4 bit quantities(nibbles): Hex 40 plus the high nibble (shifted down 4 bits) and hex 50plus the low nibble. The Host Unit on the chain with a matchingidentification number will respond by unchaining and directly connectingto the data line. This Host Unit then requests a password fromTVLINK.EXE program on the Remote PC.

A hex FF 802 is reserved as a BREAK character. When this character isreceived, it indicates that the next byte is a command or status byte.The hex 06 following 802 is a request for password and is followed bytwo bytes 803 which form an encryption. The TVLINK.EXE program thensends an encrypted password 804 to the Host Unit. If this encryptedpassword is correct, the Host Unit sends hex FF and hex 10 bytes 805which means that the Host Unit is ready and that the Host Unit has beensuccessfully accessed.

Although only one password is requested as shown in the figure, in thecurrent implementation, three to a ten passwords will be processed eachwith a unique encryption key. Only after all passwords are correctlyreceived will the Host Unit send the ready status 805. This passwordprotocol approach insures added security to the Host Unit access. If apassword is incorrect, then no more password requests will occur and theRemote PC will not be permitted access to the Host Unit.

To avoid inadvertent access to other Host Unit's while having access toa given Host Unit, hex 70 is never transmitted to the Host Unit byTVLINK.EXE program (other than during an access request 800). Instead,the two byte packet 810 is sent which is interpreted as a single bytevalue of hex 70.

Reference 827 represents data which the TVLINK. EXE program sends to theHost Unit. Reference 838 represents data which the Host Unit sends tothe TVLINK.EXE program. After the host sends the ready status 805, theTVLINK.EXE program can now issue commands to the Host Unit.

To enter remote access in text mode, the two byte command packet 820 issent. It is composed of the BREAK character (hex FF) and the commandbyte (hex 33). The Host Unit now begins a remote access mode. In thismode, data bytes sent to the Host Unit from the TVLINK.EXE program areinterpreted as keyboard scan codes which are translated and sent to theHost PC as keyboard signals. The hex value 1E at 821 is a scan codegenerated when the ‘A’ key is pressed. The hex value 9E at 822 is a scancode generated when the ‘A’ key is released.

Also, in remote access mode, video text data is captured and sent to theTVLINK.EXE program 838. This video data stream is composed of severalparts. First, the screen character address is sent, which is the BREAKcharacter 830 plus the two byte address 831. This address 831 is shownas zero, but since it is assumed upon entering remote access mode thatthe Remote PC's monitor screen has been blanked by the TVLINK.EXEprogram for the first screen's worth of data, no spaces will be sent.Thus, this starting address 831 may not necessarily be zero but willindicate the address of the first non-blank character encountered.

Next, color attribute information is sent (the BREAK character 832 withthe attribute 833). This attribute byte is a hex C0 value summed withthe 6 bit color attribute. Each bit can be represented by the form of“11rgbRGB” where the two most significant bits “11” (one,one), indicatethat this is a color attribute byte where r, g and b represent red,green and blue foreground color bits, and R, G, and B represent thebackground color bits, as more fully discussed in the narrativesupporting FIG. 5G and 5H. The value shown at 833 (hex F8) representswhite on black. The two most significant bits (hex C0) is masked off(set to zero) leaving hex 38 or 00111000b. All foreground bits (rgb)equal one and all background bits (RGB) are zero, thus meaning white onblack.

After the address and color information is sent, character code values,such as ASCII codes, follow. Reference 834 shows the hex representationof an “A” followed by a hex 42 which represents a “B” character. Afterthis, there is a color change, so 835A is sent, composed of a BREAKcharacter and the new color byte. In this case the hex F1 representsblue on black. The two most significant bits (hex C0) is masked off (setto zero) leaving hex 08 or 00001000b. Only the foreground blue bit (rgb)is equal to one and all background bits (RGB) are zero, thus blue onblack. After this a hex 43 representing a “C” character is sent 835B.This continues until and an entire screen's worth of data is sent afterwhich only the changes will be sent (thus reference 831 may take onnon-zero values). Hex value FF, used in this mode at 838, as the breakcharacter, was selected because this value does not represent a validcharacter.

In addition to the scan codes 821, 822 being sent by TVLINK.EXE programto the Host Unit 827, there are several commands which can also be sent.A refresh-screen command (hex F1) 823 instructs the Host Unit to resendan entire screen of video text as if remote access mode has just beeninvoked. This begins with another address packet 836 (identical to 830)to be sent followed by color information, then characters, etc.

Another type of command 824 sends serial mouse data 825 to the Host Unitto be forwarded to the Host PC's serial mouse input port. The content ofthis mouse data 824 in not important to either the TVLINK. EXE programor the Host Unit, it is simply passed through to the Host PC's serialmouse port.

As the Host Unit is capturing video text data, the Host PC's video modemay change to graphics mode at which point this information istransmitted to the TVLINK.EXE program as indicated at reference 837 (aBREAK character plus the graphics mode status: hex 83). At this point,the Host Unit will not send any more video text information, but willcontinue to process scan codes and commands received from the TVLINK.EXEprogram. In the current implementation, the TVLINK.EXE program will endremote access text mode by issuing a hex FF 826 (which in this usage, isnot a BREAK character) and begin remote access graphics mode. Then, theHost Unit sends a ready status (see 805) to indicate it is ready toprocess another command.

Remote access graphics mode begins by the TVLINK.EXE program sending 840(a BREAK character plus a hex 34 remote access graphics command). Atthis point the Host Unit sends video graphics data 855 and will processscan codes, mouse information or other commands 846. Scan codes areshown at references 841, 842, the refresh command causing the graphicsscreen to be “re-painted” is shown at 843, and the end graphics videomode command shown at 845. Mouse data is not shown but can also beprocessed.

The primary difference between graphics processing and text processing,is that the BREAK character value is now a hex 2A. This value was chosenbecause a hex FF, which means all pixels are on, is a common occurrencein graphics mode, so the value hex 2A was chosen instead. This modebegins by sending the starting address (the break character 850 with twobytes of graphics address information 851). It is assumed that theRemote PC's display screen is blank, and so only non-zero graphics databytes are sent. The address value 851 may be other than the zero valueshown.

In the most preferred embodiment, only graphic “snap shots” are taken.That is, after the address is sent, and the graphics data 852 has beencompletely sent, video graphics data will cease, until a refresh screencommand 843 is received, at which time the graphics data is captured andsent again (see 853). Reference 854 shows that the Host PC's video modehas changed back to text mode (a break character plus the text modestatus, hex 85). Then, the TVLINK.EXE program will end remote graphicsmode via 845 and start the remote text mode (see 820). Note that for theremote graphics mode, if a graphics data byte equals a hex 2A (same asthe break character) then a two byte packet is sent, which includes thebreak character (hex 2A) followed by the hex value A2. The TVLINK.EXEprogram will interpret this to be a hex 2A data byte.

Either the text or graphics mode can be ended at any time by issuing thehex FF character 826,845.

It is possible that the video mode may change to an unrecognized videomode or video may cease altogether (i.e. by turning the Host PC off ordisconnecting the video cable). TVLINK.EXE is notified of this event(similar to 837 and 854) by sending a BREAK character followed by a hex89 (no video present) or hex 8B (unknown video mode).

The file transfer mode is entered in a fashion similar to the videomodes just described (i.e. a BREAK character followed by the commandbyte). The Host Unit simply passes TVLINK. EXE file data through to theHost PC or vice versa after the TVFILE.EXE program has been invoked onthe Host PC to handle file transfers. The TVLINK.EXE converts all (HostUnit bound) hex 70 values to the two byte packet shown at 810 which theHost Unit will convert to a single hex 70 value before sending it to theHost PC. If TVLINK.EXE sends a hex FF character, this will end filetransfer mode. So, (Host PC bound) data values of hex FF must beconverted to a two byte packet of hex F0 plus hex 0F 811, which the HostUnit will convert to a single value of hex FF before sending it to theHost PC and TVFILE.EXE program. Other than these exceptions, the filetransfer protocol is the responsibility of the TVLINK.EXE and TVFILE.EXEprograms. In the current implementation, a modified XMODEM protocol isemployed for file transfers with the data packet size changing accordingto the number of errors encountered (line noise). The XMODEM protocol isan industry standard familiar to persons in the trade.

The current Host Unit protocol could be modified to employ a higherlevel of data transmission error detection and acknowledgment to lessenthe possibility of communication line noise causing data errors.

FIG. 9 represents an alternative embodiment of the present invention tothe preferred embodiment discussed above in which a Host Unit capturesand decodes the Host PC's VDAC video raster output signal. Under thisapproach, an Expansion adapter Card (EC) could be inserted into one ofthe available interface adapter card buss slots (e.g. 16 or 32 bitslots) within the Host PC and capture the digital video data directlyfrom the Host PC's buss as it is being send to the Host PC's VDAC. Inthis case the EC would be designed so as not to interfere with normalHost PC processing, but would simply “listen-in” on the Host PC's bussand immediately transmit any video data detected to the Host Unit via adirect cable linkage between a Host PC video data interface (e.g.serial) port and a Host PC interface port on the EC.

As shown on FIG. 9, a possible embodiment of the EC would contain it'sown microprocessor 902. Operating system software (within the associatedEPROM memory 901) would monitor video activity being sent to the HostUnit's VDAC. Any video data detected on the buss 910 would be sent outthrough the EC's video data output receptacle 903 to the Host Unit's 904(via a video data input receptacle) via 903. Because of possibledifferences in data transmission rates between the speed of the HostPC's buss and the speed at which data can be transmitted to a Host Unit,two levels of data buffering is included. To capture the video data fromthe Host PC's buss 910, several first-in first-out (FIFO's) buffers 912,914, 916 would be used. The microprocessor then reads from these FIFO's,processing the data to place it in a form ready for transmission, andstores this data in memory 900. The data in this memory is thentransmitted to the Host Unit.

The EC contains battery back-up, so that any data existing in the buffercould continue to be transmitted by the EC to the Host unit even incases where the Host Unit has failed.

Digital video data received from the EC by the Host Unit would be storedin the Host Unit and forwarded to the Remote PC following the sameprocedures described for the preferred embodiment. However, the HostUnit would no longer need to access and decode the VDAC output from theHost PC, since in this alternative embodiment the digital video datawould be supplied by the Host PC's EC.

Standard VDAC memory usage is as follows. This memory (addressed by theHost PC's microprocessor) resides on the VDAC. Monochrome text data iswritten to memory addresses starting at B000:0000. Whereas color textdata is written to addresses starting at B800:0000. Standard VGA modecolor graphics data is written to addresses starting at A000:0000 andthis represents a 64K block (which is not large enough for VGA) and isbank switched to allow total access to the entire VDAC graphics memory.Bank switching is accomplished by writing certain data bytes to VDACport addresses.

When data is written to the VDAC's video memory, whether in text mode orgraphics mode, this data will also be written to the EC's FIFO's. TheHost PC's 20 bit buss address is split between two FIFO's. The 16 bitbuss data value 911 will be written to FIFO 912. The 16 bits of the bussaddress 913 are also written to FIFO 914. The remaining 4 bits of thebuss address combined with certain control signals 915 are written toFIFO 916. These control signals are composed of a single-byte accessline and its associated high or low byte line, the write port signal,and the write memory signal. These signals 915 are analyzed (not shown)so that data will be written to the FIFO's only when addresses A000:0000through BFFF:FFFF, as well as VDAC port addresses, are written to by theHost PC's buss. Note that FIFO's need not be used and could be replacedby other circuitry to accomplish the same function.

The three FIFO's are then read by the microprocessor 902 and analyzed todetermine the kind of VDAC access, and writes appropriate output data tothe memory 900. This memory is treated as a circular buffer. When thebuffer is not empty, then data is sent via 903 to the Host Unit 904.Thus, new data is added by 902 when it is received from the FIFO's,while previously processed data is forwarded to the Host Unit.

As an alternative embodiment to a separate EC, the functions of theseparate EC could be incorporated on to a single Host VDAC. In this casethe combination VDAC would have two output ports, namely a VDM interfaceport and a Host Unit interface port for transmitting the digital videoinformation from the Host PC to the Host Unit via an interface cable.

An alternative embodiment of the Host Unit permits the Host Unit to bemore portable and easily connectable to a Host PC in cases where oneHost Unit was used to facilitate access to more than one Host PC. Thisalternative embodiment is hereinafter referred to as a “Portable HostUnit”. A Portable Host Unit would typically only be connected to a HostPC in cases where one of the Host PC's at a Host Site had failed and arepairman needed temporary access to the failed Host PC remotely toinitiate repairs. Once the repairs were completed or the problem withthe Host PC diagnosed, the Portable Host Unit could be removed from HostPC and remain at the Host site until another PC failed.

Under one possible alternative embodiment of the Host Unit, a bussinterface slot could be incorporated into the internal circuitry of thePortable Host Unit. This slot could then permit a standard internalmodem (commonly inserted into PC buss slots and familiar to persons inthe trade) to be inserted into the Portable Host Unit and therebyeliminate the need for an external modem. This approach eliminates theextra steps required for personnel at the Host Site to hook up anexternal modem to effect remote access. In addition, the Portable HostUnit would have an acoustical coupler (familiar to persons familiar withthe trade) which would be incorporated into the Portable Host Unit'scase and connected to the Portable Host Unit's internal modem to permita standard telephone headset to be used (instead of a standard telephoneline) to connect a Remote PC to the Portable Host Unit. An acousticalcoupler connection is preferred over a telephone line connection due tothe existence of intelligent business phone systems. Many such systemshave connectors, cabling and/or signals that are not compatible withstandard PC modems. Accordingly, it would be impractical for a Remote PCto establish a linkage to the Portable Host Unit unless the Host PC weremoved to a location where a telephone jack existed or a long phone cablewas run to the Portable Host Unit from wherever an available phone jackexists. An acoustical coupler permits a connection to be made to aRemote PC simply by placing the most convenient telephone's headset atthe Host site into the acoustical receptacle on the Portable Host Unit.

Under this alternative embodiment, the Portable Host Unit would beconnected to a Host PC as described in the narrative supporting FIG. 1,except (1) no direct line linkage would apply, (2) the modem at the HostSite would not be plugged directly into a telephone line and (3) noother Host Unit's would be daisy-chained to the Portable Host Unit.After the Portable Host Unit was attached to the Host PC, theTVTRAIN.EXE program could be initiated on the Host PC and the trainingprocess completed as described in narrative for FIG. 6. If this trainingprocess had been previously completed for this Host PC and the trainingparameters were stored in the Remote PC that will access the Host PC, asdescribed below, the training process need not be repeated, after thePortable Host Unit is re-attached to the Host PC. In this case, thenecessary training parameters would be uploaded from the Remote PC tothe Host Unit via the TVLINK.EXE program when the connection is firstestablished, as described below.

After the Portable Host Unit is connected to the Host PC and thetraining process completed, if applicable, a call would be initiatedfrom the Remote PC to the most convenient phone number and phoneextension, if applicable, at the Host Site where the Portable Host Unitis located. The person answering the call would place the telephoneheadset on the acoustical coupler of the Portable Host Unit to completethe telephone line linkage between the Remote PC and Portable Host Unit.If the training parameters for the Host PC being accessed are stored onthe Remote PC's mass storage device, the parameters would be up-loadedautomatically by the TVLINK.EXE program to the Portable Host Unit'snon-volatile RAM storage, immediately after the connection to thePortable Host Unit is established. Otherwise, the training parameterswould be automatically down-loaded from the Portable Host Unit'snon-volatile RAM to the Remote PC's mass storage device for use in caseswhere future access may be required to the Host PC to eliminate the needfor users at the Host Site to re-train the Portable Host Unit. Once theconnection to the Portable Host Unit and the required trainingparameters have either been up-loaded or downloaded, the Remote PC willhave access to the Portable Host Unit consistent with any other HostUnit, as previously discussed. Once Host PC is processing is complete,the Remote PC user would terminate the connection via the TVLINK.EXEprogram (see narrative for block 754A), the Portable Host Unit wouldbeep three times after the connection has ended, and someone at the HostSite would then remove the telephone headset from the acoustical couplerand return it to it's telephone cradle.

With regard to TVLINK.EXE processing on a Remote PC, when a call list isupdated (see narrative for block 715), a symbol such as “!” will be usedas part of the dialing string to indicate a call is being placed to aPortable Host Unit. When a call is placed to a Host Site (see narrativefor block 704) containing this symbol as part of the dialing string,TVLINK.EXE will either up-load or down-load Host Unit trainingparameters to or from the Portable Host Unit, automatically associatethe stored training parameters with the call-list entry, and follow theprocedures necessary to establish a connection to the Portable Host Unitvia an acoustical coupler. In addition, the TVLINK. EXE program willpreclude selecting the TVLINK.EXE menu option permitting a Remote userto switch between Host Units (see narrative for block 731), since otherHost Unit's cannot be presently daisy-chained to a Portable Host Unit.

The internal circuitry of a Host Unit presently provides a general datainterface port, herein referred to as an “AUX” port to send data out ofthe Host Unit and receive data into the Host Unit from external devices.Presently, this AUX port has several intended uses.

First, this AUX port could be programmed by the Control CPU to interfacewith a transmitter, such as an X-10 transmitter, familiar to persons inthe trade, to permit a Remote PC to control devices external to a HostUnit. For example, a Remote User could select a menu option provided bythe TVLINK.EXE program causing power to be temporarily interrupted toremote print servers on a network, forcing the print servers to rebootand reattach to a computer network that has failed and been successfullyre-started. In this example, data required by the X-10 unit to interruptpower to desired print servers would be sent by software operating inthe Control CPU to the X-10 unit connected to the AUX port. Upon receiptof such data, the X-10 unit would transmit data to an X-10 receiverswitch module used to supply AC power to each print server. Upon receiptof a command addressed to a specific X-10 switch module, AC power forthat switch module would be interrupted. Upon receipt of a secondcommand addressed to that switch module power would be restored.

Second, this AUX port could be used establish a linkage between the HostUnit and the network monitoring and trouble alert apparatus (“AlertSystem”) such as an apparatus like that described in U.S. patentapplication Ser. No. 07/966,081 filed Oct. 23, 1992 now U.S. Pat. No.5,566,339 and assigned to assignee of the present invention, thecontents of which are incorporated by reference herein. In this case,the “Alert System” could share a common phone line linkage with HostUnit(s) at a Host Site. In addition, a special “Y” style serial cableinterface would permit the Alert System to continue to transmit andreceive serial data in the same manner, as well as link the AlertSystem's serial port to the AUX port of Host Unit 00.

When an alert is received from the Alert System, the person receivingthe alert could enter a pre-set code using the keys on their touch tonephone indicating that the Alert System should suspend processing until asecond confirming tone is received from a Remote PC's modem. Then, theperson receiving the alert would activate the TVLINK.EXE program ontheir Remote PC to access the Host Site via a direct access (seenarrative for Block 711) procedure. The TVLINK.EXE program would theninstruct the Remote PC's modem to go off-hook and issue an audible touchtone code indicating the Remote PC was ready for the direct connection.Upon hearing this audible touch tone the remote user would hang up thetelephone (at which point the Remote PC will still hold the lineconnection via the PC's modem's direct connect status). Once theconfirming touch tone was received by the Alert System, the Alert Systemwould send a pre-set signal out of it's serial port to the AUX port ofHost Unit 00 instructing the Host Unit tell it's modem to go off-hook(and thereby complete the direct connection to the Remote PC). Uponreceiving this serial signal, the Host Unit's Control CPU would sendcommands out of the Data Out port to the Host Unit's modem instructingthe modem to go off hook and issue a preset touch tone confirming theHost Unit had taken the modem off hook. When the expected touch tonesfrom the Host Unit's modem are detected by the Alert System, the AlertSystem would cancel any pending phone alerts and go on-hook. At thispoint, a successful direct connection between a Remote PC and a HostSite has been accomplished after alert is received without losing thephone connection.

Synchronizing Host Unit access and Alert System processing, asdescribed, (1) permits both the Alert System and Host Unit tosuccessfully share the same phone line and thereby minimize phone linecosts, (2) prevents situations where both a Remote PC and Alert systemshare the same phone line and the Remote PC cannot access a Host Unitbecause the Alert System is using the phone line to issue alerts, (3)minimizes situations where both a Remote PC and Alert system share thesame phone line and the Alert System interferes with the Remote PC'sconnection to the Host PC by continuing to interrupt the phone line byattempting to issue pending alerts, and (4) insures the fastest possibleaccess to Host PC's in the event an alert is issued by the Alert System.

We claim:
 1. A computer monitoring system for monitoring informationdisplayed on a video display terminal connected to, and receivingdisplay information from, a data processing device comprising: videoraster signal input means for receiving a video raster signalrepresentative of said information displayed on the video displayterminal from the data processing device; and conversion means connectedto said video raster signal input means for converting said video rastersignal into a digital signal representative of said informationcontained in said video raster signals, said conversion means comprisingcharacter determination means for determining an identity of eachcharacter displayed on the video display terminal and for generating adigital code indicative of said identity of said each characterdisplayed on the video display terminal, said character determinationmeans comprising circuitry for generating a series of cyclic redundancychecks, wherein each said cyclic redundancy check is generated frompixel information associated with each character location on the videodisplay terminal.
 2. The system of claim 1 further comprisingtransmission means connected with said conversion means for transmittingsaid digital code to a remote location.
 3. The system of claim 2 furthercomprising: reception means at said remote location connected with saidtransmission means for receiving said digital code transmitted by saidtransmission means; and remote video display means connected with saidreception means for displaying said digital code received from saidreception means, said remote video display means showing an imagesubstantially the same as that shown on the video display terminal toallow a user to determine the operational status of the data processingdevice.
 4. The system of claim 3 wherein said digital code istransmitted to said remote location in response to a command receivedfrom said remote location requesting that said digital code betransmitted.
 5. The system of claim 4 further comprising interconnectionmeans for interconnecting a plurality of said computer monitoringsystems with one another and for allowing a user at said remote locationto selectively access any one of said computer monitoring systems. 6.The system of claim 1 further comprising: memory means connected withsaid conversion means for storing said digital code to retain an imageof said information displayed on the video display terminal; and controlmeans connected to said memory means and said conversion means formonitoring changes to said image and for storing said digital coderepresentative of said changes in said memory means, such that saidmemory means contains a series of image frames that can be used by anoperator to determine the cause of a system failure.
 7. The system ofclaim 1 further comprising: training means connected to said characterdetermination means for generating a predetermined character display,for operating said character determination means to generate digitalcodes representative of an identity of each character in saidpredetermined character display, and for storing said digital codesgenerated by said character determination means; and comparison meansconnected with said training means and said character determinationmeans for comparing digital codes generated by said characterdetermination means for an unknown display on said video displayterminal with said digital codes representative of each character onsaid predetermined display, such that said identity of each characterdisplayed on said unknown display can be determined.
 8. The system ofclaim 1 further comprising: synchronization signal input means forreceiving from the data processing device a horizontal synchronizationsignal; and pixel clock generating means connected with saidsynchronization signal input means and said conversion means forgenerating a pixel clock signal.
 9. The system of claim 1 wherein saiddata processing device is a personal computer, and said video rastersignal input means comprises a circuit interconnected between saidpersonal computer and the video display terminal.
 10. The system ofclaim 2 wherein said transmission means comprises a standard publicswitched telephone line.
 11. A method of receiving, analyzing andconverting information contained in an analog video raster signalgenerated by a data processing device and displayed on a video displayterminal associated with the data processing device, into a digitalrepresentation of that information comprising the steps of: receivingthe analog video raster signal generated by the data processing device;converting said analog video raster signal into a digital signalrepresentative of said information contained in said video rastersignal, said converting step including the steps of: determining anidentity of each character displayed on the video display terminal; andgenerating a digital code indicative of said identity of said eachcharacter displayed on the video display terminal, wherein said step ofgenerating a digital code comprises the step of generating a series ofcyclic redundancy checks from pixel information associated with eachcharacter location on the video display terminal.
 12. The method ofclaim 11 further comprising the step of transmitting said digital codesto a remote location.
 13. The method of claim 12 further comprising thesteps of: receiving said digital codes transmitted to said remotelocation; and displaying said digital codes to create an imagesubstantially the same as that shown on the video display terminal toallow a user to determine an operational status of the data processingdevice.
 14. The method of claim 13 wherein said step of transmittingsaid digital codes to said remote location is performed in response to acommand received from said remote location requesting that said digitalcodes be transmitted.
 15. The method of claim 12 wherein said digitalcodes are transmitted to said remote location using a standard publicswitched telephone line.
 16. The method of claim 11 further comprisingthe steps of: analyzing a predetermined character sequence displayed onthe video display terminal to determine an identity of each characterdisplayed on said video display terminal; generating a digital coderepresentative of each character in said predetermined charactersequence displayed on said video display terminal; and storing saiddigital codes in a memory.
 17. The method of claim 11 further comprisingthe steps of: receiving a horizontal synchronization signal from thedata processing device; and generating a pixel dock signal insynchronization with said horizontal synchronization signal.
 18. Themethod of claim 11 wherein said data processing device is a personalcomputer, and said video raster signal is intercepted between saidpersonal computer and the video display terminal.
 19. A computerimplemented method of converting information contained in a video rastersignal generated by a data processing device and displayed on a videodisplay terminal associated with the data processing device, into adigital representation of that information comprising the computerimplemented steps of: receiving the video raster signal generated by thedata processing device; and converting said video raster signal into adigital signal representative of said information contained in saidvideo raster signal, said converting step including the steps of:determining an identity of each character displayed on the video displayterminal; and generating a digital code indicative of said identity ofsaid each character displayed on the video display terminal, whereinsaid step of generating a digital code comprises the step of generatinga series of cyclic redundancy checks from pixel information associatedwith each character location on the video display terminal.
 20. Acomputer monitoring system for monitoring information contained in ananalog video raster signal generated by a data processing device anddisplayed on a video display terminal connected to the data processingdevice and for convening the information contained in the analog videoraster signal into a digital representation of that information fortransmission to a remote location comprising: analog video raster signalinput means connected with the data processing device for receiving saidanalog video raster signal generated by said data processing device;conversion means connected to said analog video raster signal inputmeans for receiving said analog video raster signal and for convertingsaid analog video raster signal into a digital signal comprising aplurality of digital codes representative of information contained insaid analog video raster signal, said conversion means comprisingprocessing means for analyzing said analog video raster signal, fordetermining an identity of each character displayed on the video displayterminal, and for generating at least one of said plurality of digitalcodes, said at least one of said plurality of digital codes beingindicative of said identity of said each character displayed on thevideo display terminal.
 21. A computer monitoring system for monitoringinformation contained in an analog video raster signal generated by adata processing device and displayed on a video display terminalconnected to the data processing device and for converting theinformation contained in the analog video raster signal into a digitalrepresentation of that information for transmission to a remote locationcomprising: analog video raster signal input means connected with thedata processing device for receiving said analog video raster signalgenerated by said data processing device; conversion means connected tosaid analog video raster signal input means for receiving said analogvideo raster signal and for converting said analog video raster signalinto a digital signal comprising a plurality of digital codesrepresentative of information contained in said analog video rastersignal, said conversion means comprising processing means for analyzingsaid analog video raster signal, character determination means fordetermining an identity of each character displayed on the video displayterminal and for generating a digital code indicative of said identityof said each character displayed on the video display terminal and forgenerating at least one of said plurality of digital codes, said atleast one of said plurality of digital codes being indicative of saididentity of said each character displayed on the video display terminal;and training means connected to said character determination means forgenerating a predetermined character display, for operating saidcharacter determination means to generate digital codes representativeof an identity of each character in said predetermined characterdisplay, and for storing said digital codes generated by said characterdetermination means.
 22. A remote access device to remotely control ahost computer and to receive at a remote location a video signal fromthe host computer, comprising: a remote access engine between the hostcomputer and the remote location to coordinate delivery of data packetsalong a telecommunications link between the host computer and the remotelocation; and a remote access controller, including a remote accesscontrol card communicating with the telecommunications link, to read apresent caller ID associated with the remote location, to store a listof predefined caller IDs, to compare the present caller ID with the listand to disable the remote access engine whenever the present caller IDfails to match any from the list of predefined caller IDs; and anexternal modem and a control module providing AC power to the hostcomputer, the external modem communicating with the control module andautomatically answering calls received by the external modem on adifferent telecommunications link, said control module temporarilyinterrupting power to the host computer whenever said external modemautomatically answers a call.
 23. A video digitizer for receiving analogvideo signals at a plurality of resolutions and for storing the videosignals in a video memory of a host computer comprising: a synchronizedetect circuit that detects vertical and horizontal synchronize signalsfrom an analog video signal; a microprocessor that determines a clockingrate at which the analog video signal should be sampled from the timingof the vertical and horizontal synchronize signals; a clock signalgenerator that produces a clock signal at the clocking rate; an analogto digital converter that is controlled by the clock signal to samplethe analog video signal; and a bus interface circuit that writes thesamples of the analog video signal into the video memory of the hostcomputer, wherein the clock signal generator comprises: a phase lockloop circuit that compares the phase of the horizontal synchronizesignal with the phase of a divided clocking signal; a variableoscillator that produces the clocking signal that controls the analog todigital converter, wherein the clocking signal has a frequency that isdependent on the difference in phase between the horizontal synchronizesignal and the divided clocking signal; and a programmable divider thatreceives the clocking signal produced by the variable oscillator andproduces the divided clocking signal that is fed to the phase lock loopcircuit.
 24. The video digitizer of claim 23, further comprising agating circuit that receives the clocking signal and passes the clockingsignal to the analog to digital converter during an active video portionof the analog video portion of the analog video signal.
 25. The videodigitizer of claim 23, further comprising a phase adjust circuit thatadjusts the phase of the clocking signal.